Urbani izziv, volume 33, no. 2, 2022
82
UDC: 712.256: 004.946
doi:10.5379/urbani-izziv-en-2022-33-02-02
Received: 22 March 2022
Accepted: 10 October 2022
Yasaman NEKOUI
Eduardo ROIG
Playgrounds in the digitally mediated city: An 
approach from augmented reality
Today, the use of technological devices is commonplace 
among children, which has also diminished children’s 
presence in the city. Although children, as novel citizens, 
develop some of their skills (such as social, mental, and 
educational skills) in the city, many children face some 
kind of city exclusion. Therefore, the way the physical 
environment of their city is shaped and how children in-
teract with it plays a principal role in child engagement. 
A child-friendly city can be a place to engage children us-
ing contemporary tools such as augmented reality (AR), 
which helps children communicate better and fosters 
abilities such as spatial cognition and physical and so-
cial skills in the physical and digital world. This study 
explores various examples and analyses the child-friendly 
city features of each. This article presents AR and its capa-
bilities as a potential tool utilized in the city to pave the 
way toward a child-friendly mediated city – an inclusive 
social urban environment where children play or spend 
their leisure time and effectively mature into adulthood.
Keywords: augmented reality, child-friendly cities, urban 
perception, digital cities, digital social engagement
Urbani izziv, volume 33, no. 2, 2022
83
1 Introduction
Urban environments are becoming primary contexts in which 
new generations of children will flourish, following the current 
trend of global urbanization and the growing attraction of cit-
ies for families with children (Aji et al., 2016). By 2025, the 
UN estimates that 60% of the world’s children will be living 
in cities (Krishnamurthy, 2019). UNICEF has defined the 
notion of a child-friendly city as a city where the children are 
actors with the ability to influence policy as citizens and which 
is a guarantor of all children’s rights. Children can also partic-
ipate in family, community, and social life, as well as receive 
basic health and education services while remaining safe from 
human trafficking, brutality, and mistreatment. Based on this 
concept, children have the right to feel safe on the street while 
meeting and playing with their friends, live in a non-polluted 
environment, participate in social and cultural activities, have 
accessibility to green spaces, and, regardless of their ethnicity, 
be able to access relevant services (Ceren Mavikurt, 2019).
Meanwhile, over the last few decades, rapid technological ad-
vancement has resulted in a new wave of emerging technolo-
gies that are poised to change both personal and professional 
experiences in urban spaces (Luusua, 2016). One of these 
digital technologies is augmented reality (AR), which has 
appeared in various fields, including architecture and urban 
design. Today the use of technological devices is prevalent 
among children and has been documented in many countries 
by numerous researchers in recent years. Touchscreen devic-
es such as tablets and smartphones have become significantly 
more commonplace during the past decade. More recently, 
the COVID-19 pandemic has influenced the rhythm of city 
life and substantially decreased people’s presence and activity, 
especially in urban areas. Although the lifting of restrictions 
has gradually returned cities to their normal state, this peri-
od has nonetheless caused increasing interaction of children 
with digital devices (Romanillos et al., 2021). Nowadays, the 
amount of time that children spend on mobile devices is in-
creasing. According to data from the United States, in 2020 
97% of households had at least one smartphone, 75% of fam-
ilies owned a tablet computer, and 44% of young children had 
their own tablet computer (Konca, 2021). These findings show 
that in many developed countries even a very young child can 
communicate with technology and spend a significant amount 
of time using it. However, the other side of the coin of children 
being entertained at home with a tablet, a mobile phone, or 
other technologies is their diminished presence in the city. 
Some AR games such as Pokémon Go require the user to move 
around the city to explore Pokéstops and catch items, thus 
increasing the users’ activity time and consequently improving 
their overall health and wellbeing (Potts et al., 2017; Oduor 
& Perälä, 2021).
This article investigates AR as a technology choice that chil-
dren can engage with, as an interface to encourage children 
to be in the city, and as an enabler of various factors of the 
child-friendly city. Below, we investigate three examples that 
show how AR applications can help realize some child-friendly 
city features that children can experience in their city to gain 
various useful skills through their presence in an urban envi-
ronment enhanced by the digital world. The analysis of the 
examples also exhibits features that can help engage children 
with the city to further develop and foster their interaction 
with their urban environments. The practices in this article 
are examined in developed countries but, due to the rapid 
development of technology around the world in the future, 
similar cases could be identified in most parts of the world.
The research questions are as follows:
Q1: How can children improve their urban spatial perception 
with AR?
Q2: How can today’s children become absorbed into the city 
and develop various skills via AR?
In line with the aim and research questions of this review 
article, the literature review extracted from books, articles, 
and theses is based on keywords such as augmented reality, 
augmented reality and child development, children’s presence in 
urban environments and their perception of it, and child-friendly 
cities.
1.1 Literature review
Researchers around the world have worked to develop theories, 
facts, and experiences to explain and illustrate the characteris-
tics, features, and capabilities of AR, which has attracted atten-
tion to its potential over the past decade. This review article 
adds to the research exploring the relationship between the 
city, technology, and play, developed in a doctoral programme. 
For example, Navarro Redón (2020) and Roig Segovia (2014) 
investigated the relationship between play space in the physi-
cal world and videogames, and augmented environments as a 
common ground of digital technology and traditional spatial 
structures in line with the convergence of physical and digital 
environments.
Regarding conceptual aspects of AR and its features, one can 
mention the studies by Mackay (1996), Azuma (1997), Ariso 
(2017), Saßmannshausen (2021), and other scholars that have 
explained this technology as a tool that exists in different fields 
and offers users the possibility to see the physical world en-
hanced with virtual objects superimposed upon or composited 
with the physical world (Ariso, 2017; Saßmannshausen et al., 
2021). These studies also mention that AR helps users improve 
their physical, spatial, and mental skills. Nijholt (2017a) takes 
Playgrounds in the digitally mediated city: An approach from augmented reality
Urbani izziv, volume 33, no. 2, 2022
84
a look at playfulness and playability in smart and intelligent 
cities, addressing pervasive games, urban games that change a 
city into a “gameful city”, urban experiences, and how to in-
volve residents in urban city design and development. Nijholt 
also mentions the playful hacking of smart city technology, 
mischief in smart cities, and playful interactions between res-
idents and smart city technology in public spaces.
1.2 Children and urban space
Children need to gain experiences in various environments – 
such as the home, school, and urban environments – to develop 
their abilities and skills. Outdoor activities are an opportu-
nity for children to experiment freely, run, climb, and jump 
to explore the world. To this end, cities as an outdoor space 
play an important role in children’s health, wellbeing, and 
development. Furthermore, urban spaces can provide oppor-
tunities for children’s play, social interaction, and independent 
mobility (Kyttä et al., 2018). Historical data show that while 
growing up children use the same urban spaces as adults, such 
as buildings, bazaars, public spaces, and pathways (Nooraddin, 
2020). Compared to adults, children probe their environments 
by being more physically active and playing in various ways, 
such as climbing, jumping, and balancing. In this way, children 
communicate with their environment through their preferred 
forms of activities while enjoying their time in that space. 
Streets, as an urban space used by children as a playground, 
are a place to spend time with peers and encounter adults. In 
the early 1960s, Jacobs (1961: 81) wrote that children need 
“an unspecialized outdoor home base from which to play, to 
hang around in, and to help form their notion of the world”. 
Streets and alleys could be exactly this type of space. While in 
the street, children can explore their social relations, improve 
social competencies, and gain independence. Furthermore, 
streets provide a variety of playing choices for children such as 
ball games, wheeled toys, and equipment brought from home 
(Gospodini & Galani, 2006). The other spaces that children 
use in the city are playgrounds. Playgrounds are specialized 
open spaces in towns and cities that are designed for children. 
The concept of playgrounds arose during the nineteenth cen-
tury, when the rapid growth of urbanization occurred (Metin, 
2003). Aldo Van Eyck was one of the pioneers in playground 
design. Cities, architecture, and playgrounds for children were 
his main subjects, which led him to introduce the concept of 
the city as a playground around sixty years ago in Amsterdam 
(Kim et al., 2017). Aldo Van Eyck playgrounds are simple and 
contain familiar shapes that children can easily perceive and 
communicate with (Lidón de Miguel, 2015).
In the early 1970s, the Growing Up in Cities project by Kevin 
Lynch in collaboration with UNESCO investigated how 
children’s utilization and understanding of the environment 
affects their behaviours and characteristics. That study showed 
that children learn to use the urban environment as a learning 
ground through roaming and playing in the city. The study 
was revisited, expanded, and performed in several more cities 
during the 1990s. The study also found that children that are 
involved in the social and cultural life of their city acquire 
a sense of belonging and a strong personal identity (Bourke, 
2012). Nowadays, technology plays an important role in var-
ious aspects of children’s lives, such as in games, relations with 
friends, and education. Children’s familiarity with technology 
develops day by day, and the technologies that children use 
today have also substantially changed from past decades. Chil-
dren use a variety of digital technologies for gaming, including 
video game consoles, computer games, games on phones and 
tablets, handheld video games, and augmented reality and vir-
tual reality games on various platforms (Flynn et al., 2019). 
Compared to the previous generation, today’s children also 
start their interaction with the digital world at earlier stages of 
their development of environmental perception. This further 
emphasizes the digital divide between generations. However, 
as a result of children being entertained with technology at 
home, their presence in the city is slowly diminishing. De-
veloping the use of technology toward improving the mental 
and physical activity of users in urban environments may be a 
solution to this issue. As residents of the digital city, children 
can also be entertained by healthy experiences using such tech-
nologies. In this way, children can become fonder of and more 
satisfied with the environment, which in turn improves their 
quality of life and encourages them to engage more with the 
city environment (Nijholt, 2017b).
1.3 Children’s urban perception: the 
obsolescence of traditional public space
Traditionally, perception has been understood as the process 
by which people receive information, process it, and utilize it 
to understand their environment. In this regard, Kotler (1974) 
defines perception as a thought process that involves receiving 
information, selecting, categorizing, and then interpreting it. 
People can communicate with the environment by taking part 
in it and obtaining information to perceive their surroundings. 
Norberg-Schulz (1966) states that people’s immediate aware-
ness about their environment is obtained through perception. 
This process helps humans understand, translate, and draw re-
lationships with their surroundings.
Children recognize their environment and perceive it using 
tactile, auditory, and visual senses, and they develop environ-
mental cognition by observing, questioning, and using their 
skills over time (Duzenli et al., 2019). Children’s growth and 
skill development is substantially influenced by their interac-
tion with the environment. They learn and become familiar 
Y. NEKOUI, E. ROIG
Urbani izziv, volume 33, no. 2, 2022
85Playgrounds in the digitally mediated city: An approach from augmented reality
with urban space through cognitive, affective, and evaluative 
means. Cognitive development occurs with the child’s recog-
nition of play spaces and discovering spaces, facilities, and fea-
tures. Affective development is gained through awareness and 
sensitivity to physical and environmental factors. It also alludes 
to positive feelings and emotional attachments to a place (Aziz 
& Said, 2016). Finally, evaluative development considers the 
relation of values of nature to child development. Among those 
values are aesthetic values (physical attraction and appeal of 
nature) and humanistic values (emotional affection for nature), 
which familiarize children with nature and inspire them to 
form a sense of closeness to it. Children in the urban environ-
ment become sensitive to its features, which permits them to 
explore space and communicate with it (Kellert, 2002). Chil-
dren’s experiential perception of the environment gives them 
the chance to experiment with various skills while growing up 
and helps them further develop their knowledge (Sulaiman & 
Ibrahim, 2019).
2 The opportunity of a child-friendly 
city
Creating cities for everyone and considering children’s needs 
in particular was introduced by a UNICEF initiative in Italy 
in 1996 (Titis Rum Kuntari, 2018). To address the inadequate 
attention paid to safe, secure, and healthy living conditions 
for children, a workshop was held the same year during the 
International United Nations Habitat II Conference. In this 
workshop it was reported that in a healthy habitat children’s 
wellbeing is the ultimate indicator of a healthy environment, 
decent governance, and democratic society (al Arasi, 2013).
The concept of a child-friendly city is not based on a predeter-
mined end state or closed scenario. This concept is a template 
for every city to use to make its environment, governance, and 
services more child-friendly. International conferences in re-
cent decades have led to the drafting of Agenda 21 – an action 
plan from the United Nations Conference on Environment 
and Development (United Nations, 1992) – and the Habitat 
Agenda from the Second United Nations Conference on Hu-
man Settlements (United Nations, 1996). Most recently the se-
ries of documents A World Fit for Children (UNICEF, 2008), 
intends to make cities and communities more child-friendly 
through children’s collaboration, proposing legal obligations 
and responsibilities for families, institutions, and governments 
toward realising children’s rights (Ceren Mavikurt, 2019). 
Children as residents of the city have their own perceptions 
toward their city’s surroundings, and their needs should be 
considered in the city’s design. Tonucci (2015) stated that a 
suitable city for children is an optimal city for all. Along the 
same lines, Ward (1979) emphasizes the importance of city 
design appropriate for children, which makes it convenient 
for them to live alongside other generations.
3 AR and child development
These days, AR is a technology that has been described as a live, 
direct, or indirect physical view of a real-world environment. 
AR includes the overlay of computer graphics on the physical 
world, whereby its elements are augmented or supplemented 
via videos, sounds, GPS data, or graphics created by comput-
er-generated sensory input (Hammad & Srivastava, 2017). As 
the virtual and physical worlds merge, a new type of physical 
space emerges, which could be referred to as an augmented 
urban space (Mesárošová & Hernández, 2018).
Digital technologies have been widely used by children at an 
increasingly rapid pace over the past decade. This generation 
is society’s future; children play a vital role in society’s devel-
opment and constitute a substantial customer base for the lat-
est technological advancements. Children in most developed 
countries can use contemporary technologies to play games, 
speak with friends, tell stories, and learn, which introduces 
new dimensions to learning, communication, and social inter-
action (Mridha, 2018). Furthermore, the effects of digital age 
on children’s lives are now more pronounced than ever because 
children are exposed to such technologies from a very early 
age in their homes and communities. Hence, children’s lives, 
experiences, and opportunities are becoming increasingly me-
diated by their use of digital technologies (Marsh et al., 2019).
AR can help children interact with their environment and the 
virtual world. This communication can foster spatial cognition 
and physical and social skills (Gómez-Galán et al., 2020). With 
AR, children have the potential to learn about spatial content, 
which means that children can explore and understand spatial 
relationships between digital and physical objects located in 
mediated cities (Parmaksiz, 2017). AR also enhances the per-
ception of the physical world and complements reality with 
additional sensory input to enrich children’s senses of touch, 
sight, and hearing, and it enables them to see and/or hear be-
yond what already exists in the physical world (Bozkurt, 2017; 
Kiryakova et al., 2018). AR can simulate physical entities to 
attract children and at the same time help them experience im-
aginative participation and cognitive interaction. Furthermore, 
AR helps children’s psychological development and arouses 
their desire to learn (Chen et al., 2017). According to Hedley 
and Shelton, AR interfaces are a combination of procedural 
and configurational knowledge. This technology is procedural 
knowledge because of the immersive senses that users can expe-
rience through the 3D display while standing or moving inside 
a mixed reality world. The configurational knowledge of AR is 
Urbani izziv, volume 33, no. 2, 2022
86
due to the interaction experienced by learners while holding 
a 3D model in their hands and observing the geographical 
space (Hedley & Shelton, 2004). With AR, children can thus 
perceive their environment and learn many things to develop 
their abilities and skills. On the other hand, because children 
are inherently attracted to using new technologies, tools such 
as AR should be utilized in a positive and appropriate way to 
help them improve their skills and get ready for participation 
in society. When used as a teaching tool, AR can also help 
children develop social, physical, and spatial skills.
If sufficient supervision and control are not imposed, these 
types of technologies can cause some negative effects on hu-
man health, and other problems for children, such as physical 
inactivity and addiction to technology use (Ng & Ma, 2019). 
If used incorrectly, AR, just like many other technologies, can 
make users dependent on their devices and distance them 
from society in the physical world. Because it is inevitable 
that children will use digital devices in today’s world, when 
used appropriately AR can be an opportunity for children to 
interact with the physical world. In some cases, AR can also en-
courage children to engage in physical activities. Although this 
has some complexity, it will conceivably be mitigated through 
advancements in technology in AR gadgets and applications, 
and the skills of the generation of digital natives.
4 Examples studied
Minecraft Earth, EduPARK, and UrbanAR have been select-
ed as examples due to the opportunities they provide for a 
child-friendly city with augmented features and also the oppor-
tunities they provide for children in fostering and developing 
various useful skills using AR in the urban environment. Some 
child-friendly city features that children can collaboratively ex-
perience in the physical and digital world are analysed and 
compared for these examples.
Minecraft Earth is an AR game that was developed by Mo-
jang Studios in 2009; it ended its support for the game in 
June 2021. This game brings a blocky construction set into 
the physical world. Minecraft Earth users do not pursue any 
specific goal; they can merely create, build, and explore in free-
dom while playing alone or cooperatively in a real territory or 
in an environment created by the players (Riordan & Scarf, 
2017). Here, the user can develop a scaled-down version of the 
intended AR creation on a table indoors, like when assembling 
a Lego set, and then lay it down outdoors, where it scales up 
to real-life dimensions. These virtual structures are steady and 
set to a specific location, letting any other player that visits 
that place admire or disassemble and rebuild other people’s 
creations. Minecraft Earth can be a collaborative environment 
in which multiple users can brainstorm and cooperate to make 
virtual creatures and structures (Irving, 2019).
In Minecraft Earth, a user can invite a friend using a QR code 
so that they can work together on a creation. This way, friends 
nearby that have the game installed can scan the QR code and 
join the buildplate and interact with others (Warren, 2019). 
This AR game forms communities and groups that share cre-
ative creations, demonstrating the social aspect of Minecraft 
Earth (Riordan & Scarf, 2017). In this digital world, children 
can bring their imagination to life using digital representa-
tions of various materials. Furthermore, they can play, learn, 
and explore various skills in this augmented space, which they 
can identify with and own. Minecraft Earth allows users to 
build creative structures such as buildings, streets, sidewalks, 
urban parks, entire cities, and landscapes, or even elements of 
the environment such as forests, trees, and other components. 
The base of these constructions can be real or fictional spatial 
contexts, which allows the players to create an environment 
that shows a city, a landscape, or any other place on Earth (de 
Andrade et al., 2020). Based on children’s opinions about this 
game collected from November 2019 to December 2021 on 
the Common Sense Media webpage, children like Minecraft 
Earth because it is fun and is an educational game for them 
that develops their art, creativity, and motor skills, and it is 
also appropriate for children of all age groups (Common Sense 
Media, 2019).
The EduPARK project is an AR geocaching game that devel-
ops technology-enhanced learning environments. Geocaching 
is another similar game that is based on a global positioning 
system (GPS) receiver, the internet, and users’ ability to discov-
er their environment. In this high-tech treasure-hunting game, 
users hide a cache (typically a small waterproof container) in a 
location and post its coordinates along with some clues on the 
internet (Mcnamara, 2004: 9). In the EduPARK game, a quiz 
with multiple-choice questions has been provided alongside 
content such as images, text, or audio. The game encourages 
the players to go to specific locations in the park and find the 
temporary markers or the physical caches with markers. Edu-
PARK has four stages, each one corresponding to a path with 
multiple-choice questions that the players should answer based 
on the app’s map (Pombo & Marques, 2018). The game also 
contains AR markerless tracking, which provides more oppor-
tunities for contextual and realistic learning in the park. Players 
receive a clue to a virtual cache at the end of each stage that, 
if found, rewards the players with points and virtual objects, 
which can be traded for assistance with the questions. In a sur-
vey of children that had used this game, children’s perception 
of the game was positive. In this study, 90.2% of children had 
the opinion that the app helped them learn about their envi-
ronment by showing them physical world information, and 
Y. NEKOUI, E. ROIG
Urbani izziv, volume 33, no. 2, 2022
87
86.9% of children generally had a good feeling about using this 
app for learning purposes (Marques & Pombo, 2019).
UrbanAR is an application that utilizes AR to make urban 
design more accessible to all by allowing people to express 
their opinions while having fun using it. This project allows 
people to offer their own insights and opinions regarding 
solutions to urban planning. Furthermore, municipalities can 
utilize the data and opinions of users fetched from the ap-
plication to build or rebuild cities more accurately based on 
people’s needs and desires. In this way, the project helps make 
the city a better place for everyone in a collaborative manner. 
Figure 1: a) selected screens of the EduPARK app and game (source: Pombo & Marques, 2021); b) plaque with an AR marker, next to a botanical 
specimen (source: Pombo & Marques, 2017: 176).
Figure 2: a) selected screenshots of the UrbanAR app (source. Dutch Design Daily, 2020); b) sharing ideas with other users (source: Dutch 
Design Daily, 2020).
Table 1: Examples and their features.
Opportunities through AR (digital + physical world) Child-friendly city features
Minecraft Earth
Encouraging children’s collaborative practices versus  
isolated digital practices Forming communities and groups that share  
creative creationsFostering children’s social skills by brainstorming and  
cooperating through creative processes
EduPARK
Learning about environmental contexts in the digital and 
physical world
Educational experience
Training children’s perception (touch, sight, and hearing)  
to allow sensing capacities beyond the physical world
Accessibility to green spaces
UrbanAR
Users visualize their ideas in the physical world
Effect of people’s decisions on planning and  
building their city
Collective collaboration in the urban design process
People express their point of view about urban 
features they like
Source: Authors (2022).
Playgrounds in the digitally mediated city: An approach from augmented reality
Urbani izziv, volume 33, no. 2, 2022
88
In this application, people can directly visualize their ideas in 
the physical world. Then all the builds submitted can receive 
votes from other users, which encourages mass participation 
during the process (Dutch Design Daily, 2020; UrbanAR, 
2021a). In a survey carried out by the developers of Urba-
nAR, users mentioned that the application does not depend 
on users’ subjective imagination because they can already see 
the elements in the physical world. Furthermore, they stated 
that this application helps them objectively instantiate their 
imaginations and ideas and also allows them to see the best 
arrangement of the urban elements visually (UrbanAR, 2021). 
Although this application is appropriate for all age groups, 
it especially provides an opportunity for children to develop 
their visual literacy and a sense of responsibility toward the 
city they will be living in for years to come.
Table 1 analyses the examples in terms of opportunities ren-
dered by AR and child-friendly city features. The features of 
the examples have been categorized based on the children’s 
activity and their interaction with their environment during 
the game. These features have been extracted from articles and 
the main web pages of the game developers that are referenced 
in this article.
As shown in Table 1, children gain various benefits from these 
AR games. By using AR in Minecraft Earth, children experi-
ence playing together in the digital and physical world while 
developing social skills. At the same time, they communicate 
with others and enhance their teamworking skills through the 
game’s platform. In EduPARK, children experience multiple 
modalities of AR content through text, video, and 3D models, 
which encourages them to use their senses of touch, sight, and 
hearing in the physical and digital world. With the opportuni-
ty that UrbanAR provides, users can express their insights and 
opinions throughout the urban design process and see their 
builds instantiate in the physical world. The other possibility 
that this AR application provides in its platform is that people 
can comment on each other’s work and help improve each 
other’s designs.
In each one of the three examples presented above, some of 
the child-friendly city features are evident. Children in Mine-
craft Earth associate with their friends and play with them. 
The EduPARK app is designed to be explored in an urban 
green park, a setting that can be used to promote new modes 
of learning in science education, where experiences in real 
environments improve one’s ability to understand ecosystems 
(Pombo & Marques, 2020: 2). In turn, children in UrbanAR 
can experience taking part in designing their city and bringing 
their imagination to life using digital representations.
5 Conclusion
AR facilitates the development of diverse skills among chil-
dren. In addition, it develops inquiry-based learning, spatial 
ability, and practical skills, and it can further create hybrid 
learning environments that combine digital and physical ob-
jects. In this way, AR can promote the growth of skills such 
as problem-solving, communicating, and critical thinking. As 
native digitals that are nowadays entertained with technology 
at home, children can utilize AR to be more present in the 
city and perform physical activities to develop various skills. 
Although living in the city has a pure physical form, AR can 
act as a connector to bring the physical and digital worlds 
together and help create child-friendly cities.
Based on the literature review and analysis of the examples 
selected, AR can provide the urban environment with more 
features of a child-friendly city to inspire children toward a 
more active presence in the city. As part of future work and as 
AR is more widely used in urban environments, more feedback 
needs to be collected from children around the world about 
their experience using AR in the city to more accurately quan-
tify and compare the role of AR within the child-friendly city.
Yasaman Nekoui, ETSAM School of Architecture, Universidad Politéc-
nica de Madrid, Madrid, Spain
E-mail: yasaman.nekoui@alumnos.upm.es
Eduardo Roig, ETSAM School of Architecture, Universidad Politécnica 
de Madrid, Madrid, Spain
E-mail: e.roig@upm.es
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