Drones for Civil Defense: A Case Study in the City of Niter
´
oi
Carlos Alberto Malcher Bastos
1
, Diego Passos
2,4 a
, Walace Medeiros Barbosa
5
,
Yuri Sisino Dos Santos Felipe
5
, Thais Belloti Loureiro
5
, Gilvane Dos Santos Dias
5
and Fernanda G. O. Passos
1,3 b
1
Engineering School, Universidade Federal Fluminense, Niter
´
oi, Brazil
2
Institute of Computing, Universidade Federal Fluminense, Niter
´
oi, Brazil
3
Atl
ˆ
antica Instituto Universit
´
ario, Oeiras, Portugal
4
DEETC, Instituto Superior de Engenharia de Lisboa ISEL, Lisbon, Portugal
5
Civil Defense Department, City Hall of Niter
´
oi, Niter
´
oi, Brazil
Keywords:
Drones, Unmanned Aerial Vehicle, Smart Cities, Civil Defense.
Abstract:
Nowadays, drones or Unmanned Aerial Vehicles (UAVs) are employed for several purposes such as deliver-
ing products, spreading pesticides on crops, providing internet access to remote areas, and taking videos and
photos for entertainment. In the context of smart cities it is not different. Some cities have adopted drones for
a number of important tasks, such as surveillance, traffic monitoring, and disaster management. Indeed, their
ability of reaching difficult places and the possibility of carrying different sensors and actuators make those
devices very flexible tools that can adapt to several use cases. Nevertheless, there are still obstacles — techni-
cal, regulatory or even social that can hinder the applicability of drones to certain tasks. In this work, we
report and analyze the use of drones by the Civil Defense Office of the city of Niter
´
oi, Brazil, as a case study.
In recent years, the office has been increasingly adopting drones for automatizing or simplifying a number
of processes with varying degrees of success, and intend to adopt information and knowledge management
systems to support and optimize their use. We present a list of the current drone-aided tasks performed by
the office, as well some potential applications that are not yet feasible for one reason or another. We further
analyze those obstacles and discuss what can be done to address them.
1 INTRODUCTION
Popularly known as drones, Unmanned Aerial Vehi-
cles (UAVs) are flying devices that can be used for
a variety of purposes due to their mobility and abil-
ity to collect data from a region of flight. Either au-
tonomously or controlled by a pilot, drones can carry
out remote missions replacing the human presence,
which can either enable activities that were otherwise
impossible e.g., due to the impossibility of reach-
ing a certain region of interest or, at least, mini-
mize risks and accelerate the delivery of services and
goods. For a few examples, drones have been used
for monitoring volcanic environments (de Moor et al.,
2019) and, famously, by the Amazon prime air ser-
vice (Shavarani et al., 2018).
a
https://orcid.org/0000-0002-9707-1176
b
https://orcid.org/0000-0002-6647-9822
Those two examples help illustrate the wide range
of activities that can be enabled or aided by the use
of drones. This flexibility can be explained by three
particular characteristics of these devices: their abil-
ity to fly thus allowing highly efficient and effec-
tive mobility —, as well as their capacity of carry-
ing different types of loads and their intrinsic com-
munication functionalities. More specifically, drones
can carry both sensors and actuators which can be
accessed remotely using the drone’s communication
channel with the ground station. While recreational
drones often carry cameras for video or photogra-
phy, other types of payload can be added, such as
smoke detectors, temperature sensors, speakers, or
headlights. Therefore, armed with the right payload,
drones can be adapted to countless activities. This
has popularized their usage in several different fields,
including agriculture, entertainment, industry, mili-
tary, surveillance, maritime rescue and security in-
72
Bastos, C., Passos, D., Barbosa, W., Felipe, Y., Loureiro, T., Dias, G. and Passos, F.
Drones for Civil Defense: A Case Study in the City of Niterói.
DOI: 10.5220/0011552800003335
In Proceedings of the 14th International Joint Conference on Knowledge Discovery, Knowledge Engineering and Knowledge Management (IC3K 2022) - Volume 3: KMIS, pages 72-82
ISBN: 978-989-758-614-9; ISSN: 2184-3228
Copyright
c
2022 by SCITEPRESS Science and Technology Publications, Lda. All rights reserved
spection of construction sites (Hassanalian and Ab-
delkefi, 2017; Ayamga et al., 2021).
In the context of smart cities, drone usages may
be roughly divided into three broad categories: mon-
itoring (i.e., gathering data by means of certain types
of sensors), actuation (i.e., performing actions onto
the environment) and services (i.e., serving as a com-
plimentary infrastructure). As examples, UAVs can
be used for monitoring traffic and pollution, detect-
ing accidents and wildfire, improving communication
network connectivity, and assisting city surveillance
structures (Alsamhi et al., 2019; Kim et al., 2018).
While the aforementioned activities are common
for most cities around the world, each region has its
own set of particular issues. Niter
´
oi is a Brazilian
city of about 500 thousand inhabitants a medium-
sized city by Brazilian standards —, located in the
metropolitan region of the state of Rio de Janeiro. It
is considered an ongoing smart city, with initiatives
currently under implementation through the Applied
Projects Development Program (PDPA) (Reis et al.,
2021), a partnership between the City Hall and Uni-
versidade Federal Fluminense (UFF).
Even before the PDPA, the City Hall of Niter
´
oi al-
ready used drones for a number of purposes. More
specifically, in recent years, its Civil Defense Office
has been using drones in some of the services it pro-
vides to the local population. Indeed, the expertise
developed by Niter
´
oi’s Civil Defense in the usage of
drones for the well-being of the population has be-
come a reference in Brazil, and its teams are often
deployed to help disaster-response missions around
the country, as we will detail in the rest of this paper.
Aside from those disaster-response missions, this of-
fice also provides efforts to prevent and protect the cit-
izens from natural hazards, as floods, landslides and
wildfires. In a nutshell, it works with both routine and
emergency operations in order to prevent, mitigate,
evacuate and/or recover from disasters. In that sense,
drones are used to inspect regions either where a
disaster has taken place or that have a potential for
a natural disaster —, seeking to capture information
that will help carry out rescue operations and avoid
further damage.
This work is one of the first results of DroNit, one
of the PDPA projects, which aims to optimize the use
of drones in the Civil Defense Office by applying,
among other techniques, information and knowledge
management. The paper has the specific objective of
reporting the practical experience of Niter
´
oi’s Civil
Defense Office on the use of drones. Other aspects
will be the subject of further work. We list and de-
scribe a number of current drone-aided activities per-
formed by the office, discussing how the drones have
enabled them or made them more effective. We also
highlight limitations of the currently used drones for
those tasks, pointing out the technical challenges that
hinder a more effective applicability. We further de-
scribe other activities of the Civil Defense that could
perhaps be aided by drones, but that currently not pos-
sible either for technical, regulatory or even social
reasons.
The contribution of the paper is multifold. Firstly,
it raises awareness for innovative uses of drones that
are possibly useful for other cities. Secondly, it high-
lights gaps in the current drone technology that hin-
der its usability for useful smart city applications.
Thirdly, it indicates possible research areas and open
problems regarding the usage of drones in smart
cities.
The remainder of the text is organized as fol-
lows. Section 2 reviews a number of common uses for
drones in smart cities and provides a brief overview
of the related literature. Section 3 presents our case
study of Niter
´
oi’s Civil Defense Office, describing
its typical tasks that are or could be aided by
drones. In Section 4 we highlight the main challenges
identified with the usage of drones for the activities of
the office and also discuss ideas for how the drones’
usefulness my be improved for the Civil Defense. Fi-
nally, Section 5 concludes the paper.
2 DRONES FOR SMART CITIES
AND CIVIL DEFENSE
Jensen (Jensen, 2016) addresses the theme of drones
and their potential applications in the area of smart
cities. In his work, he explores the connectivity is-
sues related to the use of drones in smart cities and
discusses how drones can improve their applications
such as surveillance, object detection, general pur-
pose distributed processing applications, data collec-
tion, route planning, tracking delivery, navigation and
collision prediction.
The implementation of a service based on the use
of drones requires studies in several aspects (Alsamhi
et al., 2019). One of them is to establish a physical
architecture, that is, choosing the drones, the types of
connectivity available, the types of sensors and actua-
tors, establishing ground stations for battery recharge,
and establishing maximum flight time considering the
measurements that will be performed. As an exam-
ple, (Kim et al., 2018) designed a framework for the
use of multiple UAVs to cover extensive areas for
surveillance. The authors consider public and private
UAVs public institutions and companies or citi-
zens, respectively analyzing aspects such as bat-
Drones for Civil Defense: A Case Study in the City of Niterói
73
tery limitation, delivery of supplies (e.g., medicine),
collision avoidance, global positioning, autonomous
flights and connectivity using standard for vehicular
communication (IEEE 802.11p) or over LTE (Long
Term Evolution) when available in the region. Still
in this context, (Katila et al., 2017) studies scenar-
ios where drones are used to monitor a large area and
transmit video information to a remote control unit
using multiple hops. To maintain a strong connectiv-
ity between drones and the control unit, the authors
used wireless mesh networks (IEEE 802.11s) at fixed
positions on the ground to increase the node redun-
dancy for routing.
Giordan et al. (Giordan et al., 2018) present a re-
view of remotely piloted aircrafts (RPAs), also known
as UAV, applied to natural hazards around the world
such as landslides, floods, earthquakes, volcanic ac-
tivity and wildfires. RPAs are used to collect data
from inaccessible regions typically from images from
conventional cameras, but also, in some cases, from
thermal sensors and multi-spectral cameras. These
RPA-gathered data are then georeferenced and pro-
cessed in order to provide, for instance, environmen-
tal and geological studies, mapping different active
processes at the Earth’s surface and analysis of river
channel vegetation.
More recently, Gohari et al. (Gohari et al., 2022)
systematically reviewed the literature of using drones
for monitoring and surveillance in smart cities, classi-
fying the papers into seven categories: transportation,
environment, infrastructure, object or people detec-
tion, disaster management, data collection and other.
Air pollution (environment) and traffic monitoring
(transportation) are the aspects more studied in the re-
cent literature. In the disaster management category,
the main areas are human body detection, evacuation
map building, fire detection, firefighting management
and search and rescue. They also associate the cat-
egories according to the number of UAVs (multiple
or single), type of UAV (mostly, with rotatory wings)
and the aerial sensors on board (mostly, conventional
camera).
2.1 Characterization of Drones
Because drones are used for so many different appli-
cations, several different offerings can be found on the
market with markedly different characteristics. Per-
haps the most fundamental way drones may differ is
in terms of typology, the most common being fixed-
wing, single-rotor, multirotor, and fixed-wing hy-
brid (Jayaweera and Hanoun, 2020). Like an airplane,
fixed-wing drones have rigid wings that provide lift
whenever the aircraft moves forward. Conversely,
single- and multirotor drones have rotating vertical
propellers for lift. While fixed-wing drones can
achieve much higher speeds, cover larger distances
and potentially carry substantial weight, single- and
multirotor drones have advantages in terms of maneu-
verability, allowing more controlled flights and the
possibility of remaining at a relatively stable position
(which often aids in tasks involving photography or
video). In particular, multirotor drones are more sta-
ble than their single-rotor counterparts, and the num-
ber of propellers usually correlates with their load ca-
pacity (Hassanalian and Abdelkefi, 2017).
Drones also vary wildly in terms of weight and
size. While consumer drones used for entertainment
can weigh as little as a few hundred grams, military
drones can weigh several hundred kilograms and be
roughly as large as some manned aircraft (Hassana-
lian and Abdelkefi, 2017). Because heavier drones
require more powerful propellers, they are also usu-
ally able to transport more load.
Another important issue is autonomy. Consumer
drones in general use electrical engines powered by
batteries which offer relatively short flight times.
Some larger capacity drones, however, use internal
combustion engines allowing for much larger auton-
omy.
While some drones may have a few autonomous
flight capabilities (e.g., avoiding collisions, returning
home under certain conditions), the most common
mode of operation has the drone being piloted re-
motely. Thus, a reliable communication between the
drone and a ground station is fundamental. Differ-
ent radio technologies can be found in different mod-
els. Some models resort to open standards, such as
IEEE 802.11, while others may employ proprietary
radio solutions DJI, for example, uses its own ra-
dio technology called OcuSync (Swinney and Woods,
2021). However, regardless of the particular technol-
ogy, consumer drones must generally operate under
unlicensed radio bands, alongside multiple compet-
ing devices, which may reduce communication per-
formance.
In terms of payload, consumer drones often carry
ordinary cameras for visible light, which can be used
both for aiding the pilot and for recording video or
taking photos. For more specialized applications,
multispectral cameras can be used e.g., infrared
can be used for monitoring vegetation growth and
coverage. Thermal cameras are also useful for find-
ing lost persons, especially under vegetation cover-
age, such as in forests. Drones equipped with a LI-
DAR can map the topography of a region and/or of
buildings. Other possibilities include sensors for tem-
perature and smoke, which can be useful for detecting
KMIS 2022 - 14th International Conference on Knowledge Management and Information Systems
74
Table 1: Main roles of the Civil Defense office of Niter
´
oi.
Id. Role Reactive Proactive
1 Identify and map risk areas, monitor slope/hill stabilization works X
2 Inspect risk areas avoiding occupations X
3 Inspect buildings, evacuating areas of risk or vulnerable buildings X
4 Inform the population about risk areas, extreme events, protocols X
5 Perform simulated exercises X
6 Collect, distribute and control supplies in disaster situations X
7 Assess damages and losses of disaster affected areas X
8 Develop citizen awareness of disaster prevention X
9 Encourage economic and production restructuring of affected areas X
10 Train human resources for civil defense and protection actions X
11 Provide data and information to the national system X
fires. Actuators can also be carried by drones. Head-
lights and loudspeakers, for example, can be used to
draw attention to the drone or to disseminate warning
messages. In agriculture, drones are often equipped
with tanks that can store liquids for irrigation or ap-
plication of pesticides. Those sensors and actuators
can either be controlled by some standalone compu-
tational device also carried by the drone or be
connected to the drone’s flight controller so that they
can be accessed remotely by the same communication
channel used to pilot the vehicle.
3 CASE STUDY: CIVIL DEFENSE
OF NITER
´
OI
In this section, we describe the main activities of the
Civil Defense Office of the Niter
´
oi City Hall and how
those activities are — or could be — aided by Drones.
The information contained here is based on several in-
terviews we conducted with the personnel of the of-
fice, as part of a process of understanding their needs,
as well as how their current experience with drones is
and what could be improved.
3.1 Roles and Daily Activities
The mission of the Civil Defense Office is regulated
by a municipal law
1
which defines the assignments of
the civil defense and protection services to the citizens
of the city of Niter
´
oi.
The overall goal of a Civil Defense office is to pro-
tect the population against natural disasters, as well
as other types of civil disturbance. This is done both
reactively — i.e., in response to particular occurrence
and, ideally, proactively i.e., by taking measures
1
Law 3561 published on December 18, 2020, avail-
able (in Portuguese) in http://leismunicipa.is/dvfyk.
that avoid or mitigate the occurrence of such events.
Table 1 presents the main roles of the office and their
classifications in relation to being reactive or proac-
tive to disaster events.
This is, of course, a broad definition and, as such,
can encompass different concrete actions for offices
of different cities. Aspects such as the city’s climate
and topography, as well as cultural trends of the pop-
ulation itself, play an important role on defining the
responsibilities and specific daily actions of a partic-
ular Civil Defense office.
Niter
´
oi, in particular, is a coastal city with tropical
climate. Temperatures are high through most of the
year, and heavy rains and storms are frequent during
the summer. The topography is quite uneven, formed
by hills spread throughout the city area. Due to this
topography and to the population density, houses and
other types of constructions are often built on those
hills.
Unfortunately, the combination of those factors
makes mudslides a common and troubling occur-
rence. Those mudslides can destroy houses and lead
to deaths. That is especially likely for illegal con-
structions, such as houses built on unstable terrains
and without the proper permits demanded by the city
hall. Thus, this is an area of particular concern to the
Civil Defense Office.
In order to avoid or mitigate tragedies related to
those mudslides, the office has to constantly monitor
the city perimeter for early signs of illegal construc-
tions. It also has to monitor areas that are particularly
vulnerable to this type of event, such as hills, check-
ing the state of vegetation coverage, as well as signs
of terrain instability.
One of the tools employed by the office for this
purpose are satellite images. Those images are re-
ceived periodically and are analyzed by technicians.
The goal is to identify and measure areas of defor-
estation, as well as possibly illegal constructions.
Drones for Civil Defense: A Case Study in the City of Niterói
75
Nevertheless, despite those preventive measures,
mudslides sometimes still occur. When they do, the
Civil Defense office is also responsible for emergency
actions, such as assessing damage, helping evacuate
the affected area, helping find survivors, as well as
making essential supplies arrive at those locations.
Because of the perennial high temperatures, natu-
ral wildfires are also a relatively common occurrence
that may pose threat to the population. As such, the
Civil Defense Office is also responsible for mapping
and monitoring vulnerable areas susceptible to fires,
such as the identification of dry vegetation.
Another common threat that is often faced by
the Civil Defense Office of Niter
´
oi are fire balloons.
Despite being a punishable offense according to the
Brazilian law, building and releasing fire balloons into
the air is still a common form of cultural expression
in several parts of Brazil. Those balloons, however,
pose a serious risk, as their paths are unpredictable —
they depend on the direction and speed of the wind
in that particular moment — and when they fall, they
can start fires. Because of that, detecting, capturing
and dealing with the consequences of illegal fire bal-
loons is also a concern of the Civil Defense in Niter
´
oi.
Aside from its duties to the population of Niter
´
oi,
the city’s Civil Defense Office also collaborates with
its peers from other cities around the country. This
happens through the exchange of information among
the offices, but also possibly in the form of direct ac-
tion in situ when severe disasters take place in other
cities.
3.2 Current Use of Drones
Many of the activities described in Subsection 3.1 can
be aided by the usage of drones. Indeed, for the past
several years, the office has been using drones for dif-
ferent purposes. The Civil Defense Office holds a
drone operation crew trained to pilot the equipment
for preventive and emergency missions.
One such use is for complementing the analysis of
satellite images. When that analysis suggests signs of
irregular constructions, for example, the office con-
ducts drone missions over the area in order to obtain
more detailed images to confirm or dismiss on the sus-
picion.
Drones are also used for providing support dur-
ing natural disasters or wildfires. In this case, the de-
vices can help quickly identifying the extension of the
affected area, as well as other potentially useful in-
formation, such as available access routes for ground
crews.
3.2.1 Actions with Drones during Emergencies
The preventive work conducted by the Civil Defense
Office is perhaps the most important because it can
avoid threats. Nevertheless, to the general popula-
tion, the actions of the office are more apparent under
emergency situations. Incidentally, these emergencies
are currently one of the main use cases of drones by
the Civil Defense Office of Niter
´
oi. Indeed, despite
its drone operation crew existing for just a few years,
it already has a significant track record of operations
of this kind.
In 2019, for instance, a fire started in a forest area
in the neighborhood of Charitas, in Niter
´
oi
2
. While
handling the fire is primarily a task of the fire depart-
ment, the Civil Defense Office provided support for
the operation. In particular, the drone operation crew
conducted survey flights that allowed the response
units to visually assess the extension of the fire, as
well as to identify the most critical fire spots. The im-
ages of that survey also allowed the fire department to
anticipate the most likely direction for the spread of
the fire and to identify possible routes for the firemen
to access the region.
More recently, in 2022, a team of the Civil De-
fense Office of Niter
´
oi was sent to the state of Bahia
to provide support to response units of that state dur-
ing a season of severe rain storms that took place by
the end of 2021
3
. One of the main tasks of this team
during this event was to help assess the state of hills
and other areas under the risk of mudslides. Among
other tools, the team employed drones to obtain de-
tailed aerial footage and images that were later ana-
lyzed by geologists and engineers to pinpoint risk ar-
eas.
A month later, the nearby city of Petr
´
opolis was
hit by a heavy storm that cause severe damage to
the infrastructure
4
and killed over 150 persons. As
they did in the storms in Bahia, a team of Niter
´
oi’s
Civil Defense Office collaborated with the local au-
thorities by using drones to identify areas in risk of
mudslides and constructions in risk of collapse. The
storm also caused a flooding that dragged vehicles, in-
cluding two busses that were carried towards a river
and sunk. Eventually, the drone operation crew of
the Civil Defense Office of Niter
´
oi was called upon
to help in the searches of missing people. By using
2
More details (in Portuguese): http://www.sma.niteroi.
rj.gov.br/index.php?option=com content&view=article&
id=5966:2019-08-05-19-01-40
3
More details: https://edition.cnn.com/2021/12/26/
americas/brazil-bahia-flooding-w/index.html
4
More details: https://www.bbc.com/news/world-latin-
america-60401611
KMIS 2022 - 14th International Conference on Knowledge Management and Information Systems
76
drones, the search process became much faster, and
larger areas were covered more quickly.
Similarly, in June 2022, heavy rains caused de-
struction in several cities in the state of Pernambuco,
in the Northeast of Brazil. Once again, Niter
´
oi’s Civil
Defense Office lent its expertise and performed drone
flights with the objective of assessing mudslide risk
areas. It also collaborated by inspecting the state of
constructions to determine which were safe for the re-
turn of the affected families.
3.2.2 Products
The Niter
´
oi’s Civil Defense Office generates products
related to their main actions in the city and services
even in other cities. These products are response to
other municipal departments about the services pro-
vided e.g. Fire Department and, ultimately, to
the population.
Frequently, the crews of Civil Defense use drones
to collect data in situ. From these data, several infor-
mation relevant to the incident or occurrence is gath-
ered and reported in documents (products). These
products are forwarded to the competent departments
of the City Hall so that actions can be taken to avoid
or handle the situation. These products are basically
reports that can include landslide areas, risk areas, soil
typology, affected properties and buildings and so on.
3.3 Demands of Drone Usage
Aside from the current uses described in Section 3.2,
other activities of the Civil Defense Office of Niter
´
oi
could be improved, facilitated or even enabled by the
employment of drones with suitable characteristics.
The inspection of constructions is one such activ-
ity. Currently, those inspections are done solely in
situ and, therefore, require a technician to physically
attend each building. Periodical drone surveys with
sufficiently detailed images could save resources by
allowing a preliminary remote evaluation of the state
of the constructions. This, in turn, may allow more
frequently inspections for each building, reducing the
risk of accidents.
Drones could also be used during events with
large concentration of people such as concerts or
protests. A drone equipped with loud speakers could
be used to disseminate audio messages containing
safety instructions or warnings regarding emergency
situations. As a more concrete example, the city has
siren systems in several mudslide risk areas that are
activated when storms are forecast. Drones could im-
prove that by spreading the warnings in regions where
the alarm system has not yet been implemented.
Another interesting possibility is the usage of
drones for transporting essential supplies e.g.,
medication during rescue operations. They could
reach difficult areas quickly and provide some kind of
first response before ground crews arrive.
Even in the activities for which the office already
uses drones, its role could be expanded for better re-
sults. For example, while the office currently uses
drones to help identify risk areas and irregular con-
structions therein, the device’s role is secondary, as
it is used only as a means for confirming or detail-
ing satellite image analysis. However, satellite im-
ages take time to obtain and sometimes are unusable
due to the presence of clouds. Thus, instead of a sim-
ple tool for confirmation or detailing, drones could be
used more frequently as a primary source of the im-
ages used for this task, mitigating the aforementioned
issues.
Another example is the handling of fire balloons,
especially during the times of the year in which this
practice is more common. The idea is to follow the
path of the balloon in order to guarantee that it will
fly to a safe area or to anticipate the areas on which it
may fall so that a proper response can be prepared.The
office could further mitigate the risks by trying to ac-
tively handle them. One possibility would be to use
drones to drag or direct the balloon to areas of lower
risk. Alternatively, drones could be used to take the
balloon down in a controlled manner — for example,
by using water or chemicals to cool down the bal-
loon’s heat source.
Further notice that drone flights can be simulated
in anticipation to a certain mission. By exploiting
that, the Civil Defense Office might conduct simu-
lated exercises and use flight simulators to assess the
most beneficial manner to deploy drones in different
situations, complementing their other teams/actions.
This would allow them to maximize the effectiveness
of the drones in real emergency situations.
4 CHALLENGES AND INSIGHTS
The activities performed by the Civil Defense Office
of Niter
´
oi surveyed in Section 3 — reveal a num-
ber of specificities that are, in many regards, differ-
ent from the most common drone uses. As such,
there are many issues identified and unique challenges
that need to be addressed, as well as lessons to be
learned from the secretariat’s experience, providing
a vast field of research and for proposals of informa-
tion and knowledge management and development of
appropriate information systems.
Drones for Civil Defense: A Case Study in the City of Niterói
77
4.1 Identified Issues and Challenges
According to the drone staff of the Civil Defense Of-
fice, the drones employed in their missions have a
flight autonomy of approximately 15 to 20 minutes
depending on the wind velocity and temperature
—, impairing actions that demand either long flight
times or large areas to be covered. To mitigate this
issue, the drone operation crew takes several backup
batteries to the missions. Still, this relatively low au-
tonomy results in interruptions in the missions as the
drones must return to the ground station so that the
batteries can be manually replaced. Also, recharging
the depleted batteries on the field is not always easy
or fast due to power outlets not always being available
on the site. Thus, this can be a limiting factor for the
length of the missions.
The weather is another issue. As described in Sec-
tion 3, several use cases of the Civil Defense Office
are concerned with rain-related emergencies. How-
ever, rain especially associated with wind is a
harsh condition for flying. Indeed, several drone mod-
els cannot fly under rain. In that case, the team needs
to postpone missions and wait for better weather con-
ditions.
Flights are also limited by the range of communi-
cation and obstacles between the radio controller and
drone. The communication range, in turn, is affected
by a number of factors, including interference levels.
As of today, the Civil Defense Office uses off-the-
shelf drones that are restricted to communication in
unlicensed bands — usually, the 900 MHz, 2.4 MHz,
and 5 GHz ISM bands. Because of their unlicensed
natures and the popularity of technologies such as
IEEE 802.11 and Bluetooth, those bands are currently
crowded in most urban areas. Thus, the communica-
tion between the drones and the ground station can be
severely affected, especially in densely populated re-
gions. Indeed, during our interviews, members of the
drone operation crew reported more than once situa-
tions where the control of the drone became unstable
likely due to communication issues.
Another problem reported by the crew is the co-
existence between drones and birds. Several missions
had to be interrupted because certain species of birds
perhaps feeling threatened by the device at-
tempted to attack the drone and disrupted the flight.
According to the pilots, this is a particularly com-
mon occurrence when drones are far away from the
ground station. The lack of visual contact with the
device makes it harder for the pilots to anticipate the
approach of the birds as they rely solely on the
relatively narrow field of view of the drone’s camera.
Nevertheless, this type of event may cause the drone
to crash.
Another challenge is how to conciliate the needs
of the Civil Defense Office with the Brazilian drone
legislation. For instance, one of Rio de Janeiro’s main
airports, Santos Dumont, is relatively close to certain
regions of Niter
´
oi. Because of the risks associated
with flying drones nearby airports, whenever a mis-
sion requires a drone flight in one of those regions, the
Brazilian legislation requires the Civil Defense Office
to register the mission with the competent department
and wait for the proper permission — in fact, off-the-
shelf drones are programmed to recognize the vicin-
ity of airports and avoid entering those areas. While
requesting this type of permission can be feasible for
routine missions that are planned ahead of time, it can
impede the usage of drones for certain emergency ac-
tions.
Legislation can also be an obstacle for other types
of desirable drone applications. Take, for instance,
the idea of using drones to carry fire balloons towards
safer areas. Overcoming the drag of a typical balloon
requires a drone of considerable size. Aside from all
the technical and financial challenges involved in de-
signing and acquiring such an equipment, there are
regulatory issues as well e.g., would there be ad-
ditional constraints regarding the areas or routes that
such a drone would be allowed to fly? what additional
permits would be required from the pilots?
Regarding Civil Defense procedures and protocols
to generate their products using drones, the agents
reported a long time (e.g., weeks) to produce them.
They need to collect the data, then process it in of-
fice and write the report outlining their conclusions.
The faster reports are generated, the faster actions are
taken on the incident. This can mean a significant im-
provement to the final result of the entire operation
demanded to the City Hall, and may even save lives.
Regardless of the model of the drone, properly
training the pilots is another important aspect. Re-
member that the Civil Defense Office missions can
occur under very challenging circumstances e.g.,
under rain, considerable wind. Moreover, the typical
missions conducted by the office often involve push-
ing the drones to their limits in terms of both auton-
omy and range. Thus, pilots must be well aware of
such limits and must be prepared to fly the drone un-
der non-ideal situations.
Finally, we note that a fundamental challenge is
choosing the right drone model. Drones can vary
widely in a number of ways e.g., size, flight au-
tonomy, load capacity, accessories. Depending on the
type of mission, certain aspects are more important
than others. For instance, search missions during a
disaster can last for days, thus requiring drones with
KMIS 2022 - 14th International Conference on Knowledge Management and Information Systems
78
Table 2: Summary of the main recommendations for each challenge or demands identified.
Challenges/Demands Recommendation Summary
Battery autonomy Multi-UAV, define points in ground for battery swap, hot-swap.
Weather conditions Investing in waterproof or splash-proof drones.
Network communication Study and use of LPWAN, 5G, FANET.
Choosing drones Survey of readily available drones on the market and sensors.
Regulation and Legislation Reduce bureaucratic processes, flexibilize rules for emergency.
Training agents Use simulators of drone flight.
Mapping risk areas Use of infrared/multispectral camera, humidity sensors, embedded in the drone.
Handling fire balloon Study techniques and procedures to extinguish or redirect balloons.
Building surveillance Define protocols for the drone structural inspection, knowledge management.
Warning sound messages Define message and protocol in missions according to historical situations.
Supply delivery Specify drone capable to transport supply. Define protocols.
More agile processes Automate procedures to provide (quasi) real-time responses while in situ.
as much autonomy as possible. However, if the search
is carried out in a region of dense vegetation, acces-
sories, such as thermal cameras, might be of great
help. Unfortunately, that adds weight, which not only
demands a larger, high-capacity drone, but also re-
duces the autonomy. Indeed, given the wide range
of different missions carried out by the Civil Defense
Office, it seems unlikely that a single drone model
will be able to cater to all requirements.
4.2 Improving or Recommending Drone
Usage
In the context of the PDPA, the Civil Defense Office
is proposing a series of potential solutions for the de-
mands and challenges mentioned in Section 4.1. Ta-
ble 2 summarizes the main recommendations, in rela-
tion to challenges and demands, as described as fol-
low.
One of the recommendations is related to the bat-
tery autonomy issue. A multi-UAV system, also
called a drone swarm, is a strategy that help solv-
ing the problem of covering larger areas (Chen et al.,
2020). Instead of using only one drone for a mis-
sion, a group of drones is autonomously coordinated
in order to embrace more tasks and consequently ex-
plore more areas. Another approach to be explored
is the organization of strategic battery charging points
in the city or at the mission site, e.g. placing vehicles
in strategic positions for this purpose. Battery hot-
swap — changing the drone’s battery without restart-
ing their electronic components and, consequently,
the previously defined mission — can also reduce the
down-time.
For the problem of flying under bad weather con-
ditions, one can consider investing in waterproof or
splash-proof drones. This, however, is not trivial, as
such models are not commonly designed by manufac-
turers in order to lower costs and reduce the technical
complexity. An alternative for the Civil Defense Of-
fice would be to develop a custom drone with this ca-
pability, which involves engineering skills.
In terms of enhancing communication, for urban
flights that suffer from interference issues in crowded
areas, the Low Power Wide Area Networks (LP-
WAN) (Chaudhari et al., 2020) technologies should
be considered for ground communication with the
UAV. Those technologies as IEEE 802.11ah and
LoraWAN operate on long distances, low bit-rate
and low battery consumption, by exploiting the less
used sub-1GHz bands. However, they are specially
geared towards low-volume traffic LoraWAN, in
particular —, being perhaps suitable for telemetry and
command transmission. Furthermore, the emergent
5G networks can also help meet the communication
demands, but the antenna placement of such networks
is often optimized for covering the ground where
most of the users of the mobile operators are. That
can be a challenge for their application for enabling
drone communications (Lin et al., 2019). One can
also consider the concept of Flying Ad Hoc Networks
(FANET), i.e., the usage of a multi-UAV system to ex-
tend the communication range by means of multi-hop
aerial communication between drones (Chen et al.,
2020).
On choosing the drone for a specific demand, a
survey of readily available drones on the market
whose purchase is more feasible — is a fundamental
step. These drones are typically composed by a body
(e.g., rotors, propellers and assembly frame), a micro-
controller, a conventional camera and a sensing sys-
tem (e.g., accelerometers, altimeter, GPS and obstacle
sensors). Kits of parts to assemble custom drones are
also available. In this case, a study of sensors and ac-
tuators is relevant to identify which sensors are more
useful for the purposes of civil defense.
Drones for Civil Defense: A Case Study in the City of Niterói
79
Regarding regulation and legislation issues, based
on the report of the Civil Defense Office, we notice
that is important streamline the bureaucratic processes
between the office and the competent government
departments especially, for the emergency mis-
sions. Since the Civil Defense Office’s services are
government-owned, the rules for emergency flights
in civilian prohibit areas, such as airports and mili-
tary zones, could perhaps be flexibilized. Of course,
flights themselves cannot become a risk for the pop-
ulation. Thus, this flexibilization might require addi-
tional effort from the part of the office, such as stricter
licenses for their pilots. A specialized system for a
quicker exchange of information between the office
and the competent departments could also help, as
well as more direct processes.
Properly training agents of the Civil Defense Of-
fice is also important. Drones can be used in several
situations and, according to the mission, they should
be included in the exercise drills. Several situations
associated with flight conditions, such as battery life,
path choice, communication failures, could be mod-
eled by simulators and help in a mission planning.
Exposing the pilot to these situations before they actu-
ally occur can be decisive for the success of the actual
missions. The usage of simulators for such purposes,
however, requires good simulation models for all as-
pects involved in the mission, including the physics
of the flight, but also communication issues, for ex-
ample.
In the context of mapping and surveillance of dis-
aster risk areas, considering the demands identified in
Subsection 3.3, we note that drones are able to mea-
sure the condition of soil and vegetation through im-
ages, if equipped with infrared and other multispec-
tral cameras. In a first moment, satellite images can
detect potential risk areas in a large but distant region.
Then, a drone assembled with an infrared camera can
examine a specific area in more detail. Drones can
also measure the relative humidity of certain regions
and other environmental aspects, if equipped with the
proper sensor (such as an air humidity sensor). These
actions can prevent disasters such as landslides, wild-
fires and irregular occupation of risk areas.
For handling fire balloons, we see a need for
studying techniques that can be used to extinguish or
redirect balloons to areas without risk of fire (such as
the sea or lake). This is not a trivial issue, as those bal-
loons are generally of large proportions — and, there-
fore, have too much drag to be pulled or carried by a
typical off-the-shelf drone. Even taking down the bal-
loon in a controllable fashion is a challenge, as cool-
ing down their heat source might require large vol-
umes of water or chemicals. As such, we anticipate
the need for a multidisciplinary effort for designing
and eventually equipping a proper drone with suitable
actuators for this task.
In terms of procedures and protocols while the
civil defense operations with drones, some proce-
dures can be automate to provide (quasi) real-time re-
sponses. We identified many information that can be
processed in situ rather than of being processed later
in the office. Thus, conclusions can be drawn more
quickly, making it possible to expand data collection
to capture additional information. Taking the example
of the inspection of risk areas, agents can compute in-
formation on risk points, based on images, still in the
field.
Defining action protocols according to a specific
mission is also key to enable the use of drones for
several demands such as building surveillance, warn-
ing sound messages and supply delivery. Protocols
must define important stages of knowledge manage-
ment and decision-making, such as the processes of
measuring data, generating storing and disseminating
the information and knowledge, and making decisions
based on acquired knowledge. Effective information
and knowledge management techniques, especially
designed for the problems discussed, are therefore
crucial for optimizing processes in the secretariat.
Table 3 summarizes the current use of drones in
the Civil Defense Office by roles (see Table 1) and
also the recommendations for future drone usage.
The difference between the current and future use of
drones by the office is highlighted in the fourth col-
umn, labeled as “Future Drone’s Use”.
5 CONCLUSION
Drones are devices responsible for collecting infor-
mation from sensors carried by them. The relative
low cost and easy access to drones especially, for
off-the-shelf models has opened-up a large num-
ber potentially useful applications. But they use of-
ten complex procedures and are therefore candidates
to benefit from information and knowledge manage-
ment systems. Smart cities, in particular, seem to be
a niche that can greatly profit from the flexibility of
drones. In this context, Niter
´
oi’s Civil Defense Office
is a pioneer in the usage of drones for a plethora of
rescue and risk prevention activities in Brazil.
In this paper, we reported on the experience of
the office in using those devices. We surveyed their
current use cases, detailing how drones have been or
could be helping the office succeed at its missions.
We also reported issues found by the office’s pilots
and technicians during their years using drones, as
KMIS 2022 - 14th International Conference on Knowledge Management and Information Systems
80
Table 3: Summary of current use of drones in the Civil Defense Office by roles and recommendations for future drones’ use.
Role
Id.
Current
Drones’ Use
Summary of the Current Usage
Future
Drones’ Use
Recommendation
1 yes Drones only inspect risk areas us-
ing conventional cameras.
yes Drones can map and identify risk
areas using infrared cameras.
2 yes Drones only inspect risk areas us-
ing conventional cameras.
yes Drones can inspect a risk area us-
ing infrared cameras.
3 no - yes Define protocols to include drones
in building inspection.
4 no - yes Drones can be used to send sound
alert messages to the civilians.
5 no - yes Apply drones in exercise drills;
use simulators of drone flights.
6 no - yes Drones can be used to transport
supplies for a risk area, if needed.
7 yes Drones capture conventional im-
ages of areas hit by disasters.
yes Drones can automate the current
process and improve evaluation.
8
Not applicable.
9
10 no - yes Drones as a tool to assist in the
training of human resources.
11 no - yes Data and procedures using drones
can feed the national system.
well as other usages that the office envisions for those
devices. We also looked at the existing challenges
in meeting those future uses, and discussed possible
paths for realizing the drones’ full potential for the
Civil Defense Office.
Towards that goal, our analysis has revealed obsta-
cles in both technical and legislative aspects of drone
usage. For example, autonomy and flight range seem
to often hinder envisioned drone applications. As bat-
tery technology evolves, those issues should be miti-
gated to a certain extent. Ditto the issues with com-
munication range, that might become less pronounced
with the proliferation of 5G. Even so, regulatory ob-
stacles also need to be overcome both by the mod-
ernization of the relevant legislation, but mainly by
the cooperation between the regulatory bodies and the
Civil Defense Office to find safe yet streamlined pro-
cesses for the authorization of time-critical missions
and the usage of specialized drones.
ACKNOWLEDGEMENTS
This work is funded by the PDPA program of the City
Hall of Niter
´
oi.
REFERENCES
Alsamhi, S. H., Ma, O., Ansari, M. S., and Almalki, F. A.
(2019). Survey on collaborative smart drones and
internet of things for improving smartness of smart
cities. IEEE Access, 7:128125–128152.
Ayamga, M., Akaba, S., and Nyaaba, A. A. (2021). Multi-
faceted applicability of drones: A review. Technolog-
ical Forecasting and Social Change, 167:120677.
Chaudhari, B. S., Zennaro, M., and Borkar, S. (2020). LP-
WAN technologies: Emerging application characteris-
tics, requirements, and design considerations. Future
Internet, 12(3).
Chen, W., Liu, J., Guo, H., and Kato, N. (2020). Toward
robust and intelligent drone swarm: Challenges and
future directions. IEEE Network, 34(4):278–283.
de Moor, J. M., Stix, J., Avard, G., Muller, C., Cor-
rales, E., Diaz, J. A., Alan, A., Brenes, J., Pacheco,
J., Aiuppa, A., and Fischer, T. P. (2019). Insights
on hydrothermal-magmatic interactions and eruptive
processes at Po
´
as volcano (Costa Rica) from high-
frequency gas monitoring and drone measurements.
Geophysical Research Letters, 46(3):1293–1302.
Giordan, D., Hayakawa, Y., Nex, F., Remondino, F., and
Tarolli, P. (2018). Review article: the use of remotely
piloted aircraft systems (RPASs) for natural hazards
monitoring and management. Natural Hazards and
Earth System Sciences, 18(4):1079–1096.
Gohari, A., Ahmad, A. B., Rahim, R. B. A., Supa’at, A.
S. M., Abd Razak, S., and Gismalla, M. S. M. (2022).
Drones for Civil Defense: A Case Study in the City of Niterói
81
Involvement of surveillance drones in smart cities: A
systematic review. IEEE Access, 10:56611–56628.
Hassanalian, M. and Abdelkefi, A. (2017). Classifications,
applications, and design challenges of drones: A re-
view. Progress in Aerospace Sciences, 91:99–131.
Jayaweera, H. M. and Hanoun, S. (2020). A dynamic artifi-
cial potential field (D-APF) UAV path planning tech-
nique for following ground moving targets. IEEE Ac-
cess, 8:192760–192776.
Jensen, O. B. (2016). Drone city – power, design and aerial
mobility in the age of “smart cities”. Geographica
Helvetica, 71(2):67–75.
Katila, C. J., Di Gianni, A., Buratti, C., and Verdone,
R. (2017). Routing protocols for video surveillance
drones in IEEE 802.11s wireless mesh networks. In
2017 European Conference on Networks and Commu-
nications (EuCNC), pages 1–5.
Kim, H., Mokdad, L., and Ben-Othman, J. (2018). Design-
ing UAV surveillance frameworks for smart city and
extensive ocean with differential perspectives. IEEE
Communications Magazine, 56(4):98–104.
Lin, X., Wiren, R., Euler, S., Sadam, A., M
¨
a
¨
att
¨
anen, H.-L.,
Muruganathan, S., Gao, S., Wang, Y.-P. E., Kauppi,
J., Zou, Z., and Yajnanarayana, V. (2019). Mobile
network-connected drones: Field trials, simulations,
and design insights. IEEE Vehicular Technology Mag-
azine, 14(3):115–125.
Reis, L. C. D., Bernardini, F. C., Ferreira, S. B. L., and
Cappelli, C. (2021). An ICT governance analysis for
the digital and smart transformation of brazilian mu-
nicipalities. In DG.O2021: The 22nd Annual Interna-
tional Conference on Digital Government Research,
DG.O’21, page 327–338, New York, NY, USA. Asso-
ciation for Computing Machinery.
Shavarani, S. M., Nejad, M. G., Rismanchian, F., and Izbi-
rak, G. (2018). Application of hierarchical facility lo-
cation problem for optimization of a drone delivery
system: a case study of amazon prime air in the city of
san francisco. The International Journal of Advanced
Manufacturing Technology, 95(9):3141–3153.
Swinney, C. J. and Woods, J. C. (2021). The effect of real-
world interference on cnn feature extraction and ma-
chine learning classification of unmanned aerial sys-
tems. Aerospace, 8(7):179.
KMIS 2022 - 14th International Conference on Knowledge Management and Information Systems
82