

2nd German-West African Conference on Sustainable, Renewable Energy Systems SusRES – Kara 2021

CPS & IOT (IIOT)

https://doi.or/10.52825/thwildauensp.v1i.35

© Authors. This work is licensed under a Creative Commons Attribution 4.0 International License

Published: 15 June 2021

Challenges of IoT deployment in the context of
developing countries

Bernardo Y. León-Ávila1 [https://orcid.org/0000-0001-7985-0224], Yunior R. Hernández-Cabrera1,
Luis A. Quintero-Domı́nguez1 [https://orcid.org/0000-0002-3527-0516],
Felipe Hernández Pentón1,
and Frank R. Quesada Espinosa1 [https://orcid.org/0000-0002-1576-6733]

1Universidad de Sancti Spı́ritus José Martı́ Pérez, Cuba

Abstract. The concept of the Internet of Things (IoT) is not exactly a novelty, even if it
has not burst out yet with all the force that the market expected. The 5th generation of
mobile telephony (5G) is rushing to deploy in the midst of a real trade war, and intends
to get one’s own way on this and others fronts. This paper analyses how to overcome
the challenges of an IoT deployment, which can be too complex to fulfil its promise of
massification and ubiquity. This analysis is primarily intended to identify whether 5G
will be the key to a current IoT deployment in all contexts, or whether it is wise to
pursue other development paths first.

Keywords: 5G, IoT, Road to Development

Introduction
Although all the current development of communication technologies has been
oriented mainly to communication between people, new trends are encouraging
machines and devices to connect massively, giving rise to Internet of Things (IoT). The
IoT represents an ecosystem that is expected to be made up of 100 billion devices by
2025: sensors, alarms, wearables, mobile phones, household appliances, code
readers, etc. According to Huawei’s estimations, on this date only 10% of the total
connections will be between humans; the rest will be between devices in autonomous
way.
Technologically speaking, when dealing with the IoT there are three layers or levels.
The first corresponds to devices, sensors and actuators whose main function is to
capture different variables such as temperature or light, which are converted into
electrical impulses (data). The second level is the "IoT gateway" or gateway, which
includes the hardware and software components that serve as a connection point
between the cloud and the controllers, sensors and intelligent devices. This level

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configure the architecture required for data processing. Finally, the third layer of the
IoT platform is where business, consumer applications and services are located [1].
The International Telecommunication Union (ITU) has created the overall roadmap for
the development of 5G mobile technology and has defined the term "IMT-2020" to
designate it. Following the completion of its work on the 5G "Vision" at the ITU
Radiocommunication Section (ITU-R) 5D Working Party meeting in San Diego,
California, the ITU defined the overall objectives, process and time frame for the
development of 5G mobile systems [2].
To fulfil its promise of massification and ubiquity, IoT requires an infrastructure
deployment that industry has been unable to supply, and 5G promises to deliver. This
paper attempts to analyze whether 5G will be the key to a current IO deployment in all
contexts, or whether it is wise to pursue other development paths first.

5G for IoT
One of the strongest reasons to think about revolutionizing mobile telecommunications
is the IoT. The 5G is intended for this purpose, and its architecture has been
redesigned by up to 36% to support the news requirements [3]
In the words of Asha Keddy, general manager of mobile standards for advance tech at
Intel, "we’ll see computing capabilities getting fused with communications everywhere,
so trillions of things like wearable devices don’t have to worry about computing power
because network can do any processing needed" [4].
The IHS Markit consulting firm has conducted a forecasting exercise through 2035
based on knowledge of the impact of previous generations of wireless technologies
and forecasts of the enormous opportunities. One of their conclusion was that “5G
value chain will generate a return of $3.5 trillion and 22 million jobs. This figure is
larger than the value of today’s entire mobile value chain” [5].
The basic performance criteria for 5G systems have been established by the ITU in its
Recommendation IMT-2020. ITU-R M.2083 describes three general usage scenarios
for 5G systems [6]:

• Enhanced Mobile Broadband, to cope with vastly increased data volumes, global
data capacity and user density

• Massive machine type communications. This use case is characterized by a very
large number of connected devices typically transmitting a relatively low volume
of non-delay sensitive data. Devices are required to be low cost, and have a very
long battery life

• Ultra-reliable and low latency communications to support mission-critical and
safety-critical applications

At this definition stage, one might ask whether the work teams will make the
standardization and regulatory decisions that make it feasible to meet these
expectations.
Figure 1 shows the increase in 5G network capabilities with respect to LTE-Advanced,
technology for 4G by the 3GPP group.

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Figure 1. Enhancement of key capabilities from IMT-Advanced to IMT-2020 [6].

The 5G still has several major challenges to overcome that may slow down its massive
deployment. The most illustrative are:

• The radio spectrum: This is probably the most important technological
challenge facing 5G communications [7]. Brett Tarnutzer, director of the
Spectrum GSMA, says "Operators urgently need more spectrum to deliver the
endless array of services that 5G will enable (...) Without strong government
support to allocate sufficient spectrum to next generation mobile services, it will
be impossible to achieve the global scale that will make 5G affordable and
accessible for everyone [7]. According with this goal, the GSMA has published
the 5G Spectrum GSMA Public Policy Position [8].

In order to support all expected performance, the ITU proposes to use the
frequency bands above 24 GHz [8]. This means that operators will need to
deploy thousands (or perhaps millions) of small cells throughout the territory: on
streetlights and urban layouts, on the facades of buildings, and even inside
individual homes, a deployment process that will be slow and require
multi-million dollar investments.

• Security issue: More data means more challenges. Let’s add that the 5G is the
first generation of mobile networks designed for M2M machine-to-machine
communication. The biggest security challenge posed by 5G networks is privacy.
5G networks will enable new types of applications and allow us to connect more

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devices to the network (and each other), encouraging us to capture and share
more and more of our personal data. Some of which may never have been
captured digitally before. In this regard, the 5G Americas group makes an
analysis of the emerging threats facing 5G and the different mitigation
mechanisms [9]. Threats that are not exactly new, but of a greater scope, so
potentially more invasive and with catastrophic effects.

• Money Matters: All the promises of 5G will not exactly be painless for mobile
ISPs. The 5G requires that the deployment of the networks responds to the
ambition of those who have designed the new technology, multiplying several
times the number of antennas and modifying their topology. The key is that, with
5G, ISP networks can be used for functions that are now impossible, significantly
extending their range of use and therefore also increasing, at least theoretically,
revenue. However, the high cost of deploying these new networks in all their
magnitude is a great challenge especially for telecommunication operators who
have to bear it, especially when the differential economic return, although
intuited, isn’t yet evident.

IoT Deployments for Developing Countries
5G promises many technological advances and a great economic boost; but without a
clear business model for all, and a prohibitive deployment cost for many economies.
Maybe this new revolution in the field of mobile technology will have to wait for better
times.
The biggest impact expected for 5G is on services and manufacturing. 5G’s main
customers are machines and objects, so in economies with weak and obsolete
industry, based on infrastructures with very poor or no automation, you will have very
few customers to help you with ROI (Return on Investment). In the end, the funds for
deployment will be taken from the development of other sectors that also need it,
sectors whose activity will be reversed in development in a faster and more objective
way.
So, if it is not wise to think about the deployment of 5G for now, it could be thought, do
we have to postpone the IoT as well? Of course not.
Although the 5G’s sellers show it as the key piece for the massive deployment of the
IoT, this concept has its own live, and has been born from several previous
technologies and paradigms, so there are always excellent options.
LPWAN
LPWA (Low Power Wide Area) or LPWAN (Low Power Wide Area Network) for many
authors. These terms do not denote any particular technology, but can be use as
generic term to refer to any network designed perfom a low-power wireless
communication with other networks, such as telephony, satellite communications or
WiFi networks.
There are several technologies based on open or proprietary standards, such as
LoRaWAN, Telensa, Sigfox, Igenu Networksentre’s Random Phase Multiple Access
(RPMA) and others. In a general sense LPWANs provide long range, promising

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coverage up to 15 Km in open environments and up to 2 Km in urban environments.
They are designed to give access to a potentially high number of devices that have to
transmit small amounts of data (few bytes) sporadically (e.g. every few minutes),
mostly to the server.
LPWA networks are used almost exclusively in the field of IoT devices and M2M
communications. Its applications are in remote meter reading, public lighting control,
theft alarms or control systems in infrastructure, crop irrigation system, unattended
weather stations, animal control, and many others.
Another great advantage of these technologies is the use of unlicensed spectrum,
although it is not in the classic 2.4GHz and 5GHz. The chips typically offer channels in
the 867 and 869 MHz bands (Europe), 902 and 928 MHz (America and Asia). The
regulations on this subject should be reviewed for non-invasive use of licensed
frequencies.
NB-IoT
Taking care your own network infrastructure, especially when there are nodes in the
field, can be quite problematic for companies that don’t want to have too large an IT
structure. It would be desirable if our mobile provider have solutions that do not include
the trauma of paying for a SIM card for hundreds of devices. The solution has been
NarrowBand - Internet of Things or NB-IoT for short.
The GSMA’s initiative, NB-IoT uses the mobile phone bands and is designed to
operate in several ways, including the use of the GSM band replacing the current
deployment (standalone). Also uses the LTE band and therefore sharing it (in-band),
or even using the spacing between LTE channels to maximize the communications
spectrum (guard-band).
NB-IoT is a half-duplex technology that enables efficient uplink communication, that is,
it allows the establishment of connection to the cellular network, the allocation of
network resources to the node (known as User Equipment or UE) and the
transmission of data (MT Data). In the most typically application, an UE will remain
disconnected from the network and, when it has data to transmit, e.g. a meter reading,
it will establish the connection, transmit the data and disconnect as soon as it receives
confirmation of delivery [10].
NB-IoT is reliable because it guarantees the data delivery. This is significant if is
compare with other LPWAN technologies based on an ALOHA access. Also, the use of
a licensed band makes it more reliable due it does not coexist with other technologies.
However, using a licensed band has implications such as being dependent on an
operator and therefore subject to a service and coverage model beyond control of the
application. E. g. if LoRaWAN used, and there is little coverage, an extra Gateway can
always be deployed; but with NB-IoT, all is on the operator’s hands.
LLNs
Like LPWA, LLNs (Low-power Lossy Network) is a set of technologies that include
devices with very limited resources, both energy, computing performance and
embedded memory. The main different with LPWA is the coverage area, just a few
meters (around 200 m). This networks are formed in multi-hop meshes to connect to

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the Internet. This idea follows the principle that multiple short jumps within a mesh are
much more energy efficient than a single jump to a sink (gateway).
As in engineering, what is usually earned in one hand is sacrificed in the other. In an
LLN, finding neighbors and then having them find a route to the gateway is not exactly
a simple task. In LLNs, nodes (known as motes) must enter their work area, recognize
their neighbors, and collaboratively find their way to the sink.
IEEE 802.15.4 is the standard for Low-Rate Wireless Personal Area Networks or
simply Low-Rate Wireless Networks from 2015. The reduction of the acronym is due
to the fact that its uses, potentialities and expectations began to go beyond the
personal area to endorse the IoT’s lines.
An important step towards the robustness of these networks was the 802.15.4e
amendment [11] which specifies the TSCH (TimeSlotted Channel Hopping)
mechanism within the multi-channel mechanism to mitigate the effects of multi-path
fading and interference generated by different commercial devices.

Conclusions
For the first time, objects are the primary customer of a commercial
telecommunications network. This is undoubtedly the most revolutionary contribution
of the 5G, which expects to deploy the massive IoT and applications with critical
performance and delay requirements. Its gradual implementation of 5G will have an
economic impact on all industrial sectors.
However, it should be keep in mind that any forecast will depend on the
implementation timetable, national regulations and the possibility of consolidating the
new business models. For now, its cost and deployment challenges are not justified in
economies with a underdeveloped infrastructure that will presumably not exploit the
capabilities and benefits of this new generation of mobile telephony.
But the IoT is not intrinsically linked to 5G. There are several solutions that can be
deployed by both public operators and other companies that wish to expand their
service portfolio using a more competitive model.

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