Horizon Report Europe. 2014 Schools Edition

Horizon Report Europe > 2014 Schools Edition
EUR 26673 EN

The Horizon Report Europe: 2014 Schools Edition examines trends, challenges, and technologies for
their potential impact on and use in teaching, learning, and creative inquiry.

The NMC Horizon Report Europe: 2014 Schools Edition
is a joint publication of European Commission’s Directorate General for
Education and Culture; European Commission’s Joint Research Centre – Institute
for Prospective Technological Studies; and the New Media Consortium.
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ISSN 1831-9424 (online) ISSN 1018-5593 (print)
doi:10.2791/83258
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© European Union 2014
Austin, Texas: The New Media Consortium, 2014
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Johnson, L., Adams Becker, S., Estrada, V., Freeman, A., Kampylis, P., Vuorikari, R., and Punie, Y. (2014). Horizon Report Europe: 2014
Schools Edition. Luxembourg: Publications Office of the European Union, & Austin, Texas: The New Media Consortium.
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Table of Contents > Click on a topic to jump to that page.
Executive Summary 1
Introduction 3
Trends Accelerating Educational Technology Adoption in European Schools 8
Fast Trends: Driving Ed Tech adoption in European schools over the next one to two years
> Growing Ubiquity of Social Media 10
> Rethinking the Role of Teachers 12
Mid-Range Trends: Driving Ed Tech adoption in European schools within three to five years
> Increasing Focus on Open Educational Resources 14
> Increasing Use of Hybrid Learning Designs 16
Long-Range Trends: Driving Ed Tech adoption in European schools in five or more years
> Evolution of Online Learning 18
> Rise of Data-Driven Learning and Assessment 20
Challenges Impeding Educational Technology Adoption in European Schools 22
Solvable Challenges: Those that we understand and know how to solve
> Integrating ICT in Teacher Education 24
> Students’Low Digital Competence 26
Difficult Challenges: Those that we understand but for which solutions are elusive
> Blending of Formal and Non-Formal Learning 28
> Creating Authentic Learning Opportunities 30
Wicked Challenges: Those that are complex to even define, much less address
> Complex Thinking and Communication 32
> Students as Co-Designers of Learning 34
Important Developments in Educational Technology for European Schools 36
Time-to-Adoption Horizon: One Year or Less
> Cloud Computing 38
> Tablet Computing 40
Time-to-Adoption Horizon: Two to Three Years
> Games and Gamification 42
> Mobile Learning 44
Time-to-Adoption Horizon: Four to Five Years
> Personalised Learning 46
> Virtual and Remote Laboratories 48
The 2014 Horizon Project Europe Expert Panel 51
Endnotes and Links 52

1
Executive Summary
W
hat is on the five-year horizon for European
schools? Which trends and technologies
will drive educational change? What are
the challenges that we consider as solvable
or difficult to overcome, and how can
we strategize effective solutions? These questions
and similar inquiries regarding technology adoption
and educational change steered the collaborative
research and discussions of a body of 53 European
experts to produce the first-ever Horizon Report Europe:
2014 Schools Edition, co-authored by the European
Commission and the New Media Consortium (NMC).
The NMC Horizon Report series charts the five-year
horizon for the impact of emerging technologies in
school communities across the globe. With more than
12 years of research and publications, it can be regarded
as the world’s longest-running exploration of emerging
technology trends and uptake in education.
Experts agreed on two major imminent trends: the
changing role of schoolteachers as a result of ICT
influence, and the impact of social media platforms,
such as Facebook and Twitter, which are already finding
their way into classrooms. These are just two of the
18 topics analysed in the Horizon Report Europe: 2014
Schools Edition, indicating the key trends, significant
challenges, and important technological developments
that are very likely to impact changes in the 28 Member
States’primary and secondary schools over the next five
years.
Looking in the mid-term period, two to three years
away, an increasing focus on open educational
resources (OER) and on the use of both traditional and
virtual learning methods are expected to have a strong
impact in Europe. These trends are also identified at the
global level for having the potential to stimulate new
models of teaching and learning by tapping the wealth
of content accessible through the Internet.
Regarding the challenges in European schools,
students’ low digital competence is considered one of
the solvable challenges. It is already being addressed
by ongoing actions of stakeholders and policy makers
across the continent, as seen in the Digital Competence
framework which has been recently endorsed by EU
Member States representatives in the Education and
Training Programme Thematic Working Group on ICT
and Education. On the other hand, having students
actively participating in the design of learning activities
is considered to be a more difficult challenge and it
lacks a clear strategy to solve it.
In view of the trends and challenges observed, the panel
also signalled the technological developments that
could support these drivers of innovation and change.
Cloud computing and tablet computing are expected
to be increasingly adopted by schools in one year’s time
or less to make use of services such as Google Apps for
Education, Skype, and Dropbox. The time-to-adoption
for educational games is estimated within two to three
years, while personalised learning and virtual and
remote laboratories are expected to be mainstream in
schools within four to five years.
To better understand the likely impact of these 18
topics on the core missions of European schools, further
analysis was conducted using a JRC-IPTS developed
framework for mainstreaming ICT-enabled innovation
for learning. This helped link the analysis to essential
questions of relevance, policy, leadership, and practice
that are needed to scale up innovative pedagogical
practices in ICT-enabled learning settings (see Chart on
page 2). While all of the topics can be described relating
in some way to each of the eight elements of the
framework, in Chart 1 they are mapped to demonstrate
the element they impact the most. The framework,
which was produced on behalf of the EC DG EAC in
the “Up-Scaling Creative Classrooms in Europe” project
(go.nmc.org/scaleccr1
), sees learning environments,
wherever they may be found, as “live ecosystems” that
evolve over time, changing in tune with the context and
culture in which they reside.

2 Horizon Report Europe: 2014 Schools Edition
Elements of the Creative Classroom Framework
Mapping the Horizon Report Europe topics to the CCR Framework
TRENDS
TR1: Growing Ubiquity of Social Media
TR2: Rethinking the Role of Teachers
TR3: Increasing Focus on Open
Educational Resources
TR4: Increasing Use of Hybrid Learning
Designs
TR5: Evolution of Online Learning
TR6: Rise of Data-Driven Learning and
Assessment
CHALLENGES
CH1: Integrating ICT in Teacher
Education
CH2: Students’Low Digital Competence
CH3: Authentic Learning
CH4: Blending of Formal and Non-Formal
Learning
CH5: Complex Thinking and
Communication
CH6: Students as Co-Designers of
Learning
TE1: Cloud Computing
TECHNOLOGIES
TE2: Tablet Computing
TE3: Games and Gamification
TE4: Mobile Learning
TE5: Personalised Learning
TE6: Virtual and Remote Laboratories
Legend of Linkages to Horizon Report Europe Topics
Assessment
Teaching practices
Learningpractices
Content & Curricula
Leadership&
Values
Infrastructure
Connectedness
Organisation
Innovative
pedagogical
practices
1 / Emotional intelligence
2 / Cross- and trans-disciplinary
3 / Open Educational Resources
4 / Meaningful activities
5 / Engaging assessment
formats
6 / Formative assessment
7 / Recognition of informal
& non-formal learning
8 / Learning by exploring
9 / Learning by creating
10 / Learning by playing
11 / Self-regulated learning
12 / Personalised learning
13 / Peer-to-peer collaboration
14 / Soft skills
17 / Multiple modes of thinking
16 / Multiple learning styles
15 / Individual strengths
Innovating services / 18
Innovative timetables / 19
Monitoring quality / 20
(Social) entrepreneurship / 22
Social inclusion & equity / 21
Innovation management / 23
Social networks / 25
Learning events / 24
Networking with real-world / 26
Physical space / 27
ICT infrastructure / 28

3
Introduction
I
n the pages that follow, 18 topics carefully selected
by the Horizon Project Europe Expert Panel related
to the educational applications of technology are
examined, all of them areas very likely to impact
technology planning and decision-making over
the next five years (2014-2018). Six key trends, six
significant challenges, and six important developments
in educational technology are placed directly in the
context of their likely impact on the core missions
of European schools, and detailed in succinct, non-
technical, and unbiased presentations. Each has been
tied to a framework that links to essential questions of
relevance, policy, leadership, and practice.
The Horizon Report Europe: 2014 Schools Edition was
produced by the New Media Consortium (NMC)
in collaboration with the European Commission’s
Directorate General for Education and Culture (EC
DG EAC), the Joint Research Centre - Institute for
Prospective Technological Studies (JRC-IPTS), Inholland
University, QIN AS, and CellCove Ltd. The internationally
recognised NMC Horizon Report series and regional NMC
TechnologyOutlooksarepartoftheNMCHorizonProject,
a comprehensive effort established in 2002 by the NMC
that identifies and describes emerging technologies
likely to have a large impact over the coming five years
in education around the globe.
The partnership’s goal for this major multi-
organisational collaboration is that the key trends,
challenges, and technological developments detailed
here directly inform policy, leadership, and practice at
all levels impacting European schools. This report aims
to help ministers, governing boards, and school leaders
to strategically approach the further evolution of
teaching, learning, and creative inquiry. Each topic has
been carefully researched and framed in the context of
its potential impact on the 28 European Union Member
States’ primary and secondary schools. Moreover,
throughout the report, references and links are made to
more than 150 European publications (reports, articles,
policy documents, blog posts etc.), projects (both EU-
funded and national initiatives) and various policy
initiatives from all over Europe.
The report’s first two sections focus on an analysis
of trends driving technology decision-making and
planning, and the challenges likely to impede the
adoption of new technologies, respectively. Each
includesanexplicitdiscussionofthetrendorchallenge’s
implications for policy, leadership, and practice in
European schools, along with examples and relevant
readings.
The third section, in which six important developments
in educational technology are described, is ultimately
framed by these trends and challenges. The adoption
or abandonment of these technologies by European
schools will be very much determined by the responses
taken across the continent to these drivers of and
obstacles to innovation and change.
Thisreportaimstohelpministers,
governingboards,andschool
leaderstostrategicallyapproach
thefurtherevolutionofteaching,
learning,andcreativeinquiry.
Findings in the Global Context
The choices of the European experts overlap in
interesting ways with those who contributed to the
globally focused NMC Horizon Report: 2014 K-12 Edition,
a sector analysis exploring technology adoption across
primary and secondary education worldwide (Table
1). The choices also share similarities with the NMC
Horizon Report: 2014 Higher Education Edition, which
looked at technology uptake across higher education
institutions, also from an international perspective.
These comparisons illuminate key themes not only in
European schools, but those whose impact is being felt
globally.
The global Horizon Project K-12 and the Horizon Project
Europe experts share a common vision that the role
of schoolteachers will significantly evolve in the next
couple of years, largely due to new developments in ICT
and their effect on shifting pedagogies. Many schools
in Europe are already reimagining teaching approaches
to support more creative technology integration as well
as more collaboration and hands-on learning among

students. Both groups also recognise the potential
influence of open educational resources (OER) and
hybrid learning designs to stimulate new models of
learning that leverage the rich tapestry of content
accessible through the Internet.
There are also overlaps in the viewpoints of the Horizon
Project Europe experts, mostly focused on schools and
school issues, and the global Horizon Project Higher
Education panel, which as the name suggests, focused
on universities and other tertiary institutions. Both
groups are seeing the proliferation of social media,
and its impact on teaching and learning. Social media
platforms, such as Facebook and Twitter, are finding
their ways into classrooms at every level of education.
As online learning continues to grow in reach and
quality, both schools and higher education are quickly
adding hybrid and other web-based elements to their
courses. These groups also see constraints, and while
the challenges are distinct in the two sectors, both
Expert Panels recognise that policy and practice need
to be updated to maximise the effectiveness of online
learning. Additionally, the global Horizon Project Higher
Education panel and the European Schools panel agree
that data-driven learning and assessment are on the
rise, with emerging areas such as learning analytics and
adaptive learning showcasing the potential to track
student behaviours to better tailor their education
pathways to their needs.
Several of the top-ranked challenges identified by the
Horizon Project Europe Expert Panel were unique to
Europe, and solidly based in local realities (Table 2).
Concerns about student competency in the digital
arena surfaced as a solvable challenge in Europe,
largely due to ongoing actions of stakeholders
and policymakers across the continent. The Digital
Competence framework is a good illustration. It has
been developed by JRC-IPTS on behalf of EC DG EAC and
recently endorsed by EU Member States representatives
in the Education and Training Programme (of ET 2020)
NMC Horizon Report
2014 Global K-12 Edition
Horizon Report Europe
2014 Schools Edition
NMC Horizon Report
2014 Global Higher Ed Edition
Fast Trends
Rethinking the Role of Teachers
Shift to Deeper Learning
Growing Ubiquity of Social Media
Integration of Hybrid Learning
Mid-Range Trends
Increasing Focus on OER
Increasing Focus on OER
Rise of Data-Driven Learning
Shift to Students as Creators
Long-Range Trends
Acceleration of Intuitive Tech
Rethinking of the School Day
Evolution of Online Learning
Rise of Data-Driven Learning
Agile Approaches to Change
Table 1: Top-Ranked Trends Across Three NMC Horizon Projects
NMC Horizon Report
NMC Horizon Report
Solvable Challenges
Authentic Learning
Personalising Learning
Integrating ICT in Teacher Ed
Students Low Digital Competence
Lack of Rewards for Teaching
Low Digital Fluency of Faculty
Difficult Challenges
Complex Thinking and Communication
Increased Concern about Privacy
Authentic Learning
Blending of Formal/Non-Formal
Competition from New Models
Scaling Teaching Innovations
Wicked Challenges
Competition from New Models
Keeping Education Relevant
Students as Co-Designers
Expanding Access to Education
Keeping Education Relevant
Table 2: Top-Ranked Challenges Across Three NMC Horizon Projects

5
Thematic Working Group on ICT and Education. Several
Member States are already trying out the framework
as a comprehensive approach to identify, describe,
and assess digital competence. The DIGCOMP report2
illuminates the issues and identifies potential solutions
— some of which are already underway. Another
distinctly European challenge is the blending of formal
and non-formal learning, which conveys the consensus
from the Expert Panel that the kinds of learning that
take place at home and elsewhere should be better
integrated into classrooms.
Additionally, the Horizon Project Europe Expert Panel
saw authentic learning and complex thinking and
communication as needing more time and concerted
efforts to flourish than indicated by the global Horizon
Project K-12 group. Both of these topics have unique
definitions and contexts in Europe as compared to
other parts of the world, justifying distinctive analyses
and different kinds of project examples. In the United
of technologies as more near-term than do schools in
general.
Both the Horizon Project Europe and the global Horizon
Project K-12 groups believe cloud computing is already
in the agenda of schools, and will be more so over
the next year. The many concrete project examples of
schools using cloud-based services such as Google
Apps for Education, Skype, Dropbox, and others show a
movement toward leveraging this technology to bolster
collaboration, digital competence, and productivity.
The Horizon Project Europe panel saw recurring
need to increase students’ access to high-calibre lab
equipment, allowing students to conduct experiments
from wherever they are, and exposing them to real
data used by major research and science organisations.
This choice underscores European school leaders’focus
on designing more authentic and frequent learning
opportunities for students.
Introduction
NMC Horizon Report
NMC Horizon Report
Bring Your Own Device (BYOD)
Cloud Computing
Cloud Computing
Tablet Computing
Flipped Classroom
Learning Analytics
Time-to-Adoption Horizon: Two to Three Years
Games and Gamification
Learning Analytics
Mobile Learning
3D Printing
Time-to-Adoption Horizon: Four to Five Years
The Internet of Things
Wearable Technology
Personalised Learning
Virtual and Remote Laboratories
Quantified Self
Virtual Assistants
Table 3: Comparison of Technologies Across Three NMC Horizon Projects
States, for example, some Horizon Project Higher
Education panellists see makerspaces as a fundamental
incarnation of authentic learning; while there are
makerspaces in Europe, other activities, including
vocational education training programmes and citizen
science initiatives are at the forefront of the European
panel discussions.
All three of these projects’ panels share some visions
for the use of educational technology in schools, as
evidenced by several overlapping topics (Table 3).
Games and gamification, for example, are perceived
to be important developments that are two to three
years away from widespread use. The three panels also
recognise the potential impact of learning analytics
and personalised learning, though the global Horizon
Project Higher Education group sees this collection
These points and comparisons provide an important
context for the main body of the report that follows this
summary. Its three major sections each highlight six rich
technology-related topics, providing carefully curated
examples and additional readings.
Methodology
To create the HorizonReportEurope:2014SchoolsEdition,
a body of 53 experts in European education, technology,
and other fields was convened in order to make the
difficult decisions on which of those topics merited
inclusion in the 2014 report, as well as determining if
any key areas had been omitted.
The 2014 Horizon Project Europe Expert Panel
represented 22 European countries, as well as several
notable international organisations, including the

European Commission, OECD, and UNESCO, and
European networks such as European Schoolnet.3
The names and affiliations of the members are listed
at the end of this report. Despite their diversity of
backgrounds and experience, the panel agreed that
each of the key trends profiled here will impact strategic
technology planning for schools in Europe; that each
of the significant challenges are impeding technology
adoption in European schools; and that each of the
six profiled technologies will influence the practice of
primary and secondary education in Europe over the
next five years.
Over the course of several months during late 2013
and early 2014, the European Expert Panel discussed
and narrowed down the topics that would appear here
in the Horizon Report Europe: 2014 Schools Edition. The
examples and readings under each topic are meant
to provide practical models as well as access to more
detailed information.
The process used to research and create the Horizon
Report Europe: 2014 Schools Edition is rooted in the
methods used across all the investigations conducted
under the banner of the NMC Horizon Project. Dozens
of meaningful trends, critical challenges, and emerging
technologies are examined for possible inclusion in the
report for each edition before the list is winnowed down
to the topics presented in the ultimate report.
To make those choices, every report draws on the
considerable expertise of a panel that first considers a
broadsetofimportanttrends,challenges,andemerging
technologies, adds those they feel are missing, and
then examines each of them in progressively more
detail, reducing the set until the final listing of trends,
challenges, and technologies is selected. This process
takes place online, where it is captured in the NMC
Horizon Project wiki. The wiki is intended to be a
completely transparent window into the work of the
project, one that not only provides a real-time view
of the work as it happens, but also contains the entire
record of the research for each of the various editions
published since 2006. The wiki used for the Horizon
Report Europe: 2014 Schools Edition can be found at
europe.wiki.nmc.org.
The procedure for selecting the topics in the report is
based on a modified Delphi process refined over the
now 12 years of producing the NMC Horizon Report
series. In late 2013, the Horizon Project Europe began
with the assembly of a distinguished panel of experts,
as in every Horizon Project cycle. The 2014 Horizon
Project Europe Expert Panel represented a wide range
of backgrounds, disciplines, and interests, and as noted
previously, 22 European countries.
The panel’s work began with a systematic review of
current literature — press clippings, reports, essays, and
other materials from the past year, or at most two years
— that pertained to a variety of aspects of emerging
technology. Panel members were provided with an
extensive set of carefully curated materials when
the project began to ensure that each worked from
a common baseline of knowledge about important
developments in technology within the past two
years. Panel members then commented on the timely
research, identified selections that seemed especially
germane, and added to the set. Using the Horizon
Project framework, any topics with potential relevance
to teaching, learning, and creative inquiry in European
schools were open for discussion. A carefully selected
set of RSS feeds from hundreds of relevant publications
ensured that the library of background resources stayed
current throughout their work.
Following this in-depth pass through the most up-to-
date resources available, the expert panel turned to the
questions that are at the core of every NMC Horizon
Project study. These questions were designed to elicit
a comprehensive dialogue around interesting trends,
significant challenges, and emerging technologies from
the panel:
1What trends do you expect to have a significant
impact on the ways in which European schools
approach the core missions of teaching, learning,
or creative inquiry and how will they impact policy,
leadership, and practice?
2What do you see as the key challenges related
to teaching, learning, or creative inquiry that
European schools will face during the next five
years, and how will they impact policy, leadership,
and practice?
3Which technologies will be most important to
teaching,learning,orcreativeinquiryinEuropean
schools within the next five years?
4Whattechnologiesmightwebemissing?Consider
these related questions:
> What would you list among the established
technologies that some European schools are
using today that arguably all European schools
should be using broadly to support or enhance
teaching, learning, or creative inquiry?
> What technologies that have a solid user base
in consumer, entertainment, or other industries
should European schools be actively looking for
ways to apply?

7
> What other technologies, from any economic
sector, do you see developing to the point that
European schools should begin to take notice of
them during the next four to five years?
After approximately two weeks of online discussions,
the responses to these questions were moved into
a special voting tool where they were systematically
ranked and placed into adoption horizons by each
expert panel member using a multi-vote system that
allowed members to weight their selections. Each
member was asked to also place their selections
into one of three categories based on, in the case of
trends, speed of the trend; for challenges, their relative
difficulty; and for technologies, when they might be
likely to enter mainstream use.4
Some 90 potential
emerging technology topics were on the table at the
beginning of the process, each accompanied by a raft of
related readings, news, research, and reports.
From the comprehensive list of trends, challenges, and
technologies originally considered, the 36 that emerged
at the top of the initial ranking process — four per
subcategory — were further researched and expanded.
With the interim results identified, the panel explored
a number of implications. For trends and challenges,
the lens was policy, leadership, and practice. For the
technologies, the criterion was adoption horizon. A
significant amount of time was devoted to formalising
these implications in the format of the NMC Horizon
Report. With that work informing the final voting, the
interim results were then ranked yet again. The topics at
the top of that ranking (six in each of the three parts of
the report) are those detailed here in the Horizon Report
Europe: 2014 Schools Edition.
Introduction

Trends Accelerating Educational Technology Adoption in
European Schools
T
he six trends described in the following
pages were selected by the project’s expert panel
in a series of Delphi-based voting cycles, each
accompanied by rounds of desktop research,
discussions, and further refinements of the topics.
These trends, which the members of the expert panel
agreed are very likely to drive technology planning and
decision-making over the next five years, are sorted into
three time-related categories — fast-moving trends
that will realise their impact in the next one to two years,
and two categories of slower trends that will realise
their impact within three to five or more years. All of the
trends listed here were explored for their implications
for European schools in a series of online discussions
that can be viewed at europe.wiki.nmc.org/Trends.
The framework of the “Up-Scaling Creative Classrooms
in Europe” (CCR) project, developed by the JRC-ITPS on
behalf of EC DG EAC and illustrated in the executive
summary, was used to map implications for policy,
leadership, and practice that are related to each of the
six trends discussed in this section. The CCR Framework
places learning environments, wherever they may
occur, as part of an ecosystem that evolves over time,
and that is very responsive to the context and culture in
which they reside. The eight-dimensional framework is
systemic by nature, and encourages the design of multi-
dimensional approaches when scaling up innovative
pedagogical practices, especially in ICT-enabled
learning settings.5
The NMC Horizon Project model derived three meta-
dimensions from the CCR framework that were used to
focusthediscussionsofeachtrendandchallenge:policy,
leadership, and practice. Policy, in this context, refers to
the formal laws, regulations, rules, and guidelines that
govern schools; leadership is the product of experts’
visions of the future of learning, based on research and
deep consideration; and practice is where new ideas
and pedagogies take action, in schools, classrooms, and
related settings.
Policy. While all of the identified trends had policy
implications, two trends in particular are expected to
have a strong impact on policy decisions over the next
five years. As social media have pervaded many aspects
ofourinformallives,numerousapplicationsforteaching
and learning have been developed. Current initiatives
acrossEuropeseektoformalisetherelationshipbetween
social media platforms and classroom activities, and it
begins with designing effective policies. One goal of the
“EU Kids Online,” for instance, is to create guidelines for
safe and effective use of these sites.6
While the panel experts also believe that open
educational resources will reach their maximum impact
in European schools within three to five years, policy
makers are already taking actions to make quality
resources available to teachers, including the Flemish
Ministry of Education’s KlasCement website, which
showcases best practice examples of OER in use.7
TheCCRFrameworkplaceslearning
environments,wherevertheymay
occur,aspartofanecosystem
thatevolvesovertime,andthatis
veryresponsivetothecontextand
cultureinwhichtheyreside.
Leadership. Although there are leadership
implications highlighted for all the identified trends
as well, two trends, specifically in the realm of online
learning, stand out as unique opportunities for vision
and leadership. First, the rise of digital learning has
called into question traditional education paradigms
where learning almost exclusively takes place face-
to-face. The integration of hybrid learning designs
— a combination of both the traditional and virtual
— into education is expected to be commonplace in
the next two to three years, and is already apparent in
non-formal learning communities for teachers. After
researchers at the Eindhoven University of Technology
in the Netherlands analysed 26 online professional
development communities, they concluded that both
virtual learning and face-to-face learning are most
effective when used together. The study they published

9
provides recommendations for scaling these kinds of
hybrid experiences.8
Positioned as a long-range trend, online learning
practices are evolving to incorporate more emerging
ICT and authentic, interactive learning experiences.
There is room for leadership in terms of establishing
best practices and preparing online content. The EU-
funded“Teachers’Aids on Creating Content for Learning
Environments 2”(TACCLE2) offers practical guidance for
teachers using online environments for their classes, as
well as discipline-specific content.9
Practice.Eachofthesixtrendsidentifiedbytheexpert
panel has numerous implications for teaching and
learning practice, and in many cases, current examples
are easy to find. It is widely agreed that expectations for
teachers are evolving rapidly, especially as models such
as student-centred learning and hands-on learning are
increasingly emphasised by ministries of education and
school administrations. The panel of experts believes
there will be a major transformation in the role of
teachers within the next two years, and there is already
evidence of this in the way technologies are being used
during class. A European consortium called Innovative
Technology for Collaborative Learning and Knowledge
Building, for example, created MapTool, an interactive
display with which students are collaborating on mind
maps to help them sort through complex subject
matter.10
Finally, the panel perceives the rise of data-driven
learning and assessment for European schools is at
least five years away from large-scale use. A number of
schools are integrating learning analytics in order to get
an accurate sense of how — and how well — students
are grasping the subject matter. Flint High School in the
UK, for example, uses the online “Itslearning” platform
so that teachers and students can access real-time
assessments of their knowledge acquisition through
activities both inside and outside of the classroom.11
The following pages provide a discussion of each of
the trends highlighted by this year’s expert panel that
includes an overview of the trend, its implications, and
curated recommendations for further reading on the
topic.
Key Trends

FastTrend: Driving EdTech adoption in European schools over the next one to two years
S
ocialmediaarechangingthewaypeopleinteract,
present ideas and information, and judge the
quality of content and contributions. More
than 1.2 billion people use Facebook regularly
accordingtonumbersreleasedinOctober2013;12
thetop10socialmediaplatformsworldwidereachmore
than2.1billionpeople,accordingtoeBizMBA.13
Arecent
report by the firm eMarketer reported social networks
reach nearly one in four people around the world —
almost 25% of the world population.14
As of February
2014, the agency We are Social shared that there were
around 300 million active social media users in Europe,
accounting for 40% of the continent’s population.15
Teachers and students routinely use social media to
communicate with each other and keep up to date on
assignments.16
As social networks continue to flourish
inEurope,educatorsarealsousingthemasprofessional
communities of practice, as learning communities, and
as a platform to share interesting stories about topics
studentsarestudyinginclass.
CCR Framework Element: Connectedness
Overview
Inmanyways,theincreasinguseofsocialmediainschools
is being fuelled by its common use in everyday life across
Europe. A recent study by Internet World Stats revealed
that 63% of Europe’s Internet-connected population
uses Facebook, compared to just over 30% for the rest of
the world.17
Many of these subscribers (some 175 million
people) log on daily to catch up on news and share
content. Millions more use Twitter, which has become
a major news source with more and more journalists
and media outlets breaking news stories there. Social
media have now proliferated to the point where they
span all ages and demographics. According to the Office
for National Statistics and Eurostat, the largest groups,
primarily 6-24 year-old users, are concentrated in the UK,
the Netherlands, and Sweden.18
Early use of social networks established them as a place
to share pictures, video, and stories, but as social media
have evolved, their long term value has coalesced
around the ways these platforms make it easy to connect
to family, friends, and especially for education, people
of similar interests. When users log in to Facebook and
Twitter, two of the sites that have the most subscribers
and daily traffic, they are there to see what their family,
friends, and favourite organisations are doing and who is
talking about what.19
For schools, social media provides
a way to encourage feedback and suggestions, even
as it enables two-way dialogues between students,
parents, teachers, and the institution that are less formal
than other means. Parents, for example, use groups in
WhatsApp to connect with each other and stay informed
about school happenings.20
School-age students commonly use social media to
connect with their peers for all sorts of reasons, and
understanding how social media can be leveraged
for social learning — and how to avoid common
missteps — has come to be a key skill for teachers.
Initial teacher education and continuing professional
development (CPD) programmes are increasingly
expected to include these topics. Ann Michaelsen, a
teacher and administrator in Norway, recently showed
BETT Conference participants in London how to use
Skype, YouTube, blogs, and Twitter to forge connections
between students and experts,21
but educators can
also access professional forms of social media as well.
Teachers across Europe are creating and participating in
communities of practice via LinkedIn groups — “Prime
Teachers Network”22
and “Teaching English in Europe”23
are two example groups in a growing set. Schools are
using LinkedIn to announce open teaching positions
and evaluate potential candidates.
Implications for Policy, Leadership, or
Practice
With social media use rapidly growing across Europe,
there is a need for schools to develop policies and
guidelines so that students can better and more safely
leverage these platforms and tools for learning. In the
Netherlands, the Kennisnet Foundation launched the
“Social Media in Education” project to provide example
applications and protocols. They published Social Media
in School, which explores tips for teachers that include
integrating Facebook into homework assignments,
creating photography lessons around Instagram,
and using Twitter for regular communications with
students.24
Several related publications detail guidelines
for preventing misuse of social media, especially
cyberbullying. EU Kids Online aims to make social media

11
use by students safer and more productive, especially
for the many 9-12 year-olds who use social networks
underage.25
The Staff Working Document of the EC’s “Opening
Up Education” explores the benefits of integrating
social media into education, including ways that social
media can be used to make learning environments
more dynamic, flexible, and open, while extending
learning beyond the school day and in the home.26
Also
addressed in the document are potential challenges;
in the EU, 75% of teachers have been using computers
and the Internet at school for at least four years, but
this usage has centred around creating lessons. Many
teachers have not demonstrated expertise in weaving
social media into their pedagogies, and as a result, the
document calls for more education programmes and
development opportunities.
For Further Reading
The following resources are recommended for those who
wish to learn more about the growing ubiquity of social
media:
Media Education in Four EU Countries (PDF)
go.nmc.org/mediafour
(Kennisnet Foundation, October 2013.) This report
explores social media policies in Finland, Sweden, the
UK, and the Netherlands as it relates to the rise in digital
competency and safe web usage. > Policy
3 Reasons Why the School Principal Needs to Tweet
go.nmc.org/need
(Mark W. Guay, The Huffington Post, 6 December 2013.)
Social media such as Twitter are part of the landscape in
which the important skills of research, content creation,
and networking are applied, and principals can be
role models in demonstrating how to navigate social
networks. > Leadership
The Facebook Guide for Educators
go.nmc.org/eduk
(The Facebook Guide for Educators, The Education
Foundation, 2013.) The Education Foundation, along
with Wellington College and London Nautical School,
developed a social media guide that illustrates how to
support teaching across multiple subjects. > Leadership
How Social Media Helps Bridge the Gap Between
Home and School
go.nmc.org/home
(Rebecca Ratcliffe, Guardian Professional, 18 September
2013.)To keep parents involved, UK teachers at Mereside
School blog and tweet about what their children do
in class, using tools like Evernote to share students’
portfolios. > Practice
Social Media Transforms the Textbook Lesson
go.nmc.org/soctran
(Carolyn Rice, BBC News, 30 January 2014.) Students at
Sandvika High School in Norway use Quadblogging
software, which allows four schools to meet online to
read and exchange information with students in other
countries. > Practice
Why LearningThrough Social Networks Is the Future
go.nmc.org/plns
(Paul Moss, TechThought, 26 November 2013.) Social
networks are important for both teachers and students,
and the author argues that they must become a feature
of school curriculum. > Practice
Fast Trend
Forschools,socialmediaprovides
awaytoencouragefeedbackand
suggestions,evenasitenables
two-waydialoguesbetween
students,parents,teachers,
andtheinstitutionthatareless
formalthanothermeans.
There remains considerable room for leadership,
especially in documenting creative social media
projects that demonstrate the benefits of social media
for education, but many schools are making progress,
and there are some notable successes. In Romania,
the “eSafety4eTwinners” project at Caransebes School
aims to decrease dropouts by encouraging students
to demonstrate knowledge acquisition through social
media, while also documenting the process on a wiki for
other teachers looking to implement similar activities.27
Caransebes students are using Glogster to view and
create interactive presentations, as well as a Facebook
Group for easy and private sharing. Learn2Teach
convened students from vocational training colleges in
six EU countries to present outcomes of their ICT-based
social media studies. The presentations demonstrated
how social media are transforming the way students
communicate and influencing deeper learning in the
classroom.28

FastTrend: Driving EdTech adoption in European schools over the next one to two years
T
eachers are increasingly expected to be adept
at a variety of ICT-based and other approaches
for content delivery, learner support, and
assessment; to collaborate with other teachers
bothinsideandoutsidetheirschools;toroutinely
use digital strategies in their work with students and
act as guides and mentors; and to organise their own
work and comply with administrative documentation
andreportingrequirements.Students,alongwiththeir
families, add to these expectations through their own
use of ICT to socialise, organise, and informally learn
on a daily basis, and many education thought leaders
argue that schools should be providing ways for
students to continue to engage in learning activities,
formal and non-formal, beyond the traditional school
day. As this trend gathers steam, many schools across
Europe are rethinking the primary responsibilities of
teachers. Related to these evolving expectations are
changes in the ways teachers engage in their own
continuing professional development, much of which
involves social media and online tools and resources.
While fully online schoolwork is still relatively rare on
the continent, an increasing number of teachers are
using more hybrid and experiential learning scenarios,
and experimenting with social media and other ways
of building learning communities.
CCR Framework Element: Teaching Practices
Overview
As schools make the shift to more student-centred
learning, they are also faced, as a matter of course, with
rethinking the functions of teachers. In ideal scenarios,
the teacher’s role is becoming that of a mentor, visiting
with groups and individual learners during class to help
guide them, while allowing them to have more of a say
in their own learning. This trend has led to a number
of Europe-wide efforts to aggregate best practices
and create new resources for the 21st century teacher.
For example, eTwinning is an online community and
collaboration space for schools across Europe.29
Primary
and secondary students are able to write and share
ideas, and collaborate on school projects with other
students through the use of ICT, social media, and more.
Increasing pressure is being placed on teachers not only
to understand how to use these types of tools, but also
to integrate them in ways that foster more authentic
learning.
Greater accessibility to the Internet also continues
to spark profound changes in traditional paradigms.
Teachersarenolongertheprimarysourcesofinformation
and knowledge for students when a quick web search is
at their fingertips. Instead it is up to teachers to reinforce
the habits and discipline that shape life-long learners
— to ultimately foster the kind of curiosity that would
compel their students to continue beyond an Internet
search and dig deeper into the subject matter. In order
to be prepared to guide learners in this manner, teachers
are increasingly expected to be knowledgeable on
the practices, skills, and resources that will be useful
to students as they continue their education and seek
gainful employment.
One visible example of the transformation of teaching
is the Education & Training for Entrepreneurship
initiative, which aims to make youth more employable
through the inclusion of creativity, business thinking,
and training in the standard school curriculum.30
As
part of this effort, the European Commission published
Entrepreneurship Education: A Guide for Educators, which
refers to the teacher as a coach, as someone who
listens to students, helps them harness ideas, incites
collaboration and interaction, and introduces practical
knowledge and experience of the working world.31
Integrating entrepreneurship in education has provided
the foundation for the kind of training and professional
development that will be necessary for teachers as
technology brings new forms of education to the
forefront and highlights the importance of developing
life-long learning strategies in the global economy.
Practice
Key to nurturing the new role of teachers is providing
them with plentiful opportunities for professional
development. In 2013, the European Commission
published the report Key Data on Teachers and
School Leaders,32
which calls for continuous learning
opportunities for teachers in order for them to
adapt to the 21st century pedagogies. According to
the publication, CPD is now mandatory for career
advancement in some Member States, including

13Fast Trend
Romania, Slovenia, and Croatia. Another key European
Commission document, the Strategic Framework for
Education and Training,33
hopes to incite forward-
thinking policy-making, which includes considering
alternative means of gaining teaching qualifications,
reassessing the support available to teachers, and
awarding additional monetary allowances. Several EU
Member States are already revising their initial teacher
education and continuing professional development
programmes in order to prepare them for their new
roles. Towards this direction, the EC’s Supporting the
Teaching Professions for Better Learning Outcomes reports
on the essential steps, for example, emphasising the
critical need for induction support for new teachers and
CPD for in-service teachers.34
The publication outlines
ten key actions to support improved teaching, including
redefining the qualities required for the position.
Part of finding success in this changing landscape is
determining the right balance in how class time is used,
which is one of the underlying notions of a teaching
model that is gaining momentum in Europe — the
flipped classroom. In this model, rather than the teacher
using class time to instruct and dispense information,
that work is done by each student before or after class,
and could take the form of collaborating with their peers
inonlinecommunities,curatingonlinecontent,watching
video lectures, listening to podcasts, and more. In 2013,
the EU-funded project Creative Classrooms Lab held a
design and implementation workshop that resulted in a
report called Policy Maker Scenario: Flipped Classroom. It
promotes a shift in practice to more student-controlled
learning, which teachers can foster through the use of
technologies, such as tablets and apps for note-taking
and content creation, along with the use of virtual
learning environments.35
Policy makers at the workshop mentioned above
envisioned the teacher’s role as discussing with students
how to take notes properly by sharing successful
examples, equipping them with presentation skills,
and assessing their learning through the content they
have created. Across Norway, several successful flipped
classroom models are already underway, including those
at Sandgotna Secondary School,36
Hundsund Lower
Secondary School,37
and Sandvika High School,38
where
teachers are assigning video lectures for homework and
reserve class time for in-depth discussions and active
problem-solving.
For Further Reading
The following resources are recommended for those
who wish to learn more about rethinking the role of
teachers:
Supporting Teacher Competence Development for
Better Learning Outcomes
go.nmc.org/support
(European Commission, July 2013.) The
recommendations in this report are the result of a peer-
learning process between experts on teacher education
nominated by 26 countries and by European bodies of
stakeholders that drew shared conclusions about how to
implement effective policies. > Policy
Is theTraditional Role of aTeacher Outdated? (Video)
go.nmc.org/isthe
(Skoll World Forum, 11 April 2014.) In this video from the
SkollWorld Forum, education leaders discuss how recent
innovations, technological advances, and resource
scarcity all affect the way students learn, challenging the
definition of a teacher. > Leadership
Towards Teacher-Led Design Inquiry of Learning
go.nmc.org/inqui
(Valerie Emin-Martinez et al., The Open University,
2014.) This paper proposes teacher-led design inquiry
of learning as a new model of educational practice
and professional development that integrates teacher
inquiry into student learning, learning design, and
learning analytics. > Leadership
How a Radical New Teaching Method Could Unleash
a Generation of Geniuses
go.nmc.org/radical
(Joshua Davis, WIRED, 15 October 2013.) The author
exploreshowaprimaryschoolteacherinaruraltownwas
able to improve student performance by implementing
inquiry-based instruction techniques learned through
videos on the Internet. > Practice
Moving Education into the Digital Age: the
Contribution of Teachers’Professional Development
go.nmc.org/moving
(P. Twining et al., Journal of Computer Assisted Learning,
5 August 2013.) Research indicates that effective
models of teacher education require changes at several
levels of educational systems, and that ICT presents an
opportunity to introduce new structures and roles that
support these changes. > Practice
The Uncomfortable Truth about Personalised
Learning
go.nmc.org/plearn
(Stephen Laster, Gigaom, 2 September 2013.) The Chief
Digital Officer at McGraw Hill-Education lists the three
skills modern teachers should have in order to take
advantage of personalised learning. > Practice

Increasing Focus on Open Educational Resources
Mid-RangeTrend: Driving EdTech adoption in European schools within three to five years
O
pen educational resources (OER) are growing
in breadth and quality, as is the use of these
materials in classrooms, networks, and school
communities. The use and adoption of OER
materials is increasingly a matter of policy in
schools, especially in the many disciplines in which
high quality educational content is more abundant
than ever. Understanding that the term “open” is a
multifaceted concept is essential to following this
trend; often mistaken to simply mean “free of charge,”
advocates of OER have worked towards a common
vision that defines it more broadly — not just free in
economic terms, but also in terms of ownership and
usage rights. The goal is that OER materials are freely
copiable, freely remixable, culturally sensitive, and
free of barriers to access, sharing, and educational
use. The 2012 UNESCO Paris OER Declaration has
been a crucial document for defining open as it relates
to the creation, circulation, and standardisation of
educational resources.39
CCR Framework Element: Content & Curricula
Overview
In 2013, the EU identified the development of OER as
one of three actions of the “Opening Up Education”
initiative proposed to bring the digital revolution to
schools and universities.40
As part of this initiative, a web
portal called “Open Education Europa” was launched.41
The portal is an expansion of an existing community that
has been serving teachers since 2002. Today, it enables
teachers, students, policy makers, and stakeholders to
access existing European OER, MOOCs, the eLearning
Papers journal, transnational projects, and forums where
members exchange their experiences and ideas on the
use of OER.
Together, these multinational efforts are an important
precursor to the widespread adoption of OER for
teaching and learning, and reflect a shift in the way
European leaders are conceptualising education. The
focus is increasingly moving to the process of learning
than on the body of information conveyed. Information,
in this view, is everywhere; the challenge is to make
effective use of it. OER is seen as a way to do that. New
licensing and IP schemes, led by efforts such as the
Creative Commons, encourage not only the easy sharing
and adaptation of educational materials, but also the
exchange of pedagogies and instruction techniques.
Part of the appeal of OER is that they are a response to
both the rising costs of traditionally published resources
and the related lack of educational resources in some
regions. Actively in development in both the private and
public sectors are business models to ensure that OER
can be sustainable, credible, and up-to-date resources
for teaching and learning.42
As a result, development of OER policy and distribution
methods has advanced rapidly in Europe, supported by
a number of high-profile projects dedicated to solving
the remaining challenges so that the use of OER can
realistically become widespread. The EU-funded project
“Policies for OER Uptake” (POERUP) is a collaborative
effort by institutions in Europe and Canada to compile
research about existing OER policies throughout the
world to support policy development.43
In the Report
on Comparative Analysis of Transversal OER Initiatives,
it was noted that of the 120 notable initiatives studied
throughout North America, Europe, and the Gulf States,
nearly half are related to digital assets, while 20% are for
open textbooks, and 29% are open courses.
ThegoalisthatOERmaterialsare
freelycopiable,freelyremixable,
culturallysensitive,and
freeofbarrierstoaccess,
sharing,andeducationaluse.
Practice
A major consideration of OER initiatives lies in resolving
intellectual property issues to ensure that the resources
shared are free and adaptable for anyone and for any
purpose. To this aim, there has been significant progress;
led by a founding member of the Polish Coalition for
Open Education, the “Open Educational Resources
Policy Project in Europe” is an effort by the Creative
Commons and its European affiliates to ensure that all

15
educational content that is produced in Europe through
public funding is licensed for free use.44
The initiative’s
three main activities are focused on coordinating a
community of Creative Commons affiliates and OER
activists, developing a policy position with supporting
research along with the publication of an informative
manual about the benefits of open education, and
conducting meetings with key decision making bodies
and other stakeholders.
While there are focused efforts to publicly finance the
development of streamlined platforms to create and
distribute open content, much work is yet to be done to
ensure the quality and completeness of OER. There are
three ways in which OER quality is commonly verified: by
the users and/or community; by a peer review process;
or by adherence to an established quality assurance
criterion.The Norwegian National Digital Learning Arena
employs a top-down model using criteria developed by
Norway’s Centre for ICT to ensure that published OER fall
within their standards. On the other side of the spectrum,
a bottom-up approach is used to ensure the quality of
open textbooks for “Book in Progress,” a web resource
for Italian secondary schools in which a subject teacher
works with a subject coordinator to validate the text.45
To aid teachers with integrating OER into their classroom
practices, the “OER Commons” is an online hub for
content curation and training that was developed by
the Institute for the Study of Knowledge Management
in Education.46
The “OER Commons” provides teacher
education on the use and creation of learning materials
with Open Author, a three-step online publisher that
licences and shares the content with the“OER Commons”
community. In addition to offering face-to-face training
sessions with the “Teachers as Makers Academy,”47
the project also provides a year-long mentorship
programme and webinar trainings as part of the “OER
Fellowship Programme.”48
Other forms of professional
development for European teachers in the use of OER
exists, but is typically limited to the OER community
within the teacher’s home country; “OER Commons” is
a model for teacher education that transcends national
boundaries and provides a variety of training options to
teachers everywhere.
For Further Reading
who wish to learn more about the increasing focus on
open educational resources:
The Cyfrowa Szkoła Programme in Poland
go.nmc.org/cyfrow
(Cyfrowa Szkoła, accessed 17 February 2014.) The
Cyfrowa Szkoła is a government programme in Poland
that is implementing technical training and OER
provisioning pilots to determine the best selection of ICT
equipment and methods for raising teachers’ technical
competences in teaching. > Policy
eQNet Travel Well Criteria
go.nmc.org/eqn
(Learning Resources Exchange for Schools, accessed
6 February 2014.) “eQNet” is a three-year project
coordinated by European Schoolnet that involves nine
ministries of education. This EU-funded project has
published a set of “Travel Well” criteria that any teacher,
repositoryowner,publisher,orvendorcanusetoidentify
and flag digital learning content with high potential for
re-use. > Leadership
Open Education Europa
go.nmc.org/openup
(European Commission, accessed 16 February 2014.)The
EC launched“Opening Up Education”to increase the use
of publicly funded OER in schools and universities and
promote the acquisition of digital skills. This web portal
contains regularly updated information about the OER
and free learning opportunities. > Leadership
Open Educational Resources InfoKit
go.nmc.org/infokit
(JISC, accessed 16 February 2014.) As part of the JISC
“Open Educational Resources Programme,” a kit of
resources was compiled to help educators understand
OER and how they can be integrated into learning
activities. > Leadership
KlasCement
go.nmc.org/klasce
(KlasCement, accessed, 14 February 2014.)“KlasCement”
started in 1998 as a resource website for primary
and secondary teachers in Belgium to share teacher-
generated content. As of 2014, it is part of the Ministry of
Education. The site now includes OER suitable for cross-
border usage and examples of best practices. > Practice
The Potential of Open Educational Resources (PDF)
go.nmc.org/pote
(JRC-IPTS, January 2013.) This presentation highlights
the major current OER initiatives in Europe and how they
are affecting educational practices. > Practice
Mid-Range Trend

Increasing Use of Hybrid Learning Designs
Mid-RangeTrend: Driving EdTech adoption in European schools within three to five years
A
s teachers and students alike become more
familiar with and adept at using the Internet,
traditional classroom pedagogies increasingly
include online learning components, hybrid
learning strategies, and increased focus on
collaboration within the classroom. Schools that are
making use of hybrid learning models are finding
that using both the physical and the virtual learning
environments to their highest potentials allows
teachers to engage students in a broader variety
of ways, and even extend the learning day. Hybrid
models, when designed and implemented effectively,
enable students to use the school day for group
work and project-based activities, while using the
network to access readings, videos, and other learning
materials on their own time, leveraging the best of
both environments.
CCR Framework Element: Organisation
Overview
A renewed interest in online learning has taken place
over the past few years, fuelled in large part by press
attention to massive open online courses (MOOCs),
but also by increased access to the Internet and
broadband services, and a growing recognition that
online learning can indeed add value to almost any
learning environment. Hybrid learning models, which
blend the best of classroom instruction with the best of
web-based delivery, place a strong emphasis on using
school time for peer-to-peer collaboration and teacher-
student interaction, and placing independent learning
into online environments.49
The flipped classroom is one
pedagogical example of hybrid learning that requires
students to engage with web-based content at home,
usually video lessons, while class time is repurposed
as an opportunity for teachers to mentor individuals
and groups, and for students to problem solve and
work together with classmates. The distinction is in the
degree to which the Internet components are woven
into the curricular design.
The International Association for K-12 Online Learning’s
(iNACOL) latest survey of global online and blended
learning initiatives shows that while online learning
options are commonly available to students in the EU,
only a handful of countries, such as Denmark, Finland,
and Romania, have made it part of their national
agendas to fund hybrid learning initiatives for primary
and secondary students.50
While not part of national
agendas yet, other countries are encouraging schools
to experiment with hybrid models. In the Steve Jobs
Schools in the Netherlands, for example, students use
their personal tablet devices to access educational
resources both inside and outside of school. A host of
innovative resources have been developed to facilitate
this blended experience including a virtual campus
called “sCoolSpace,” which allows children and their
teachers to meet offsite.51
In a recent Talking Futures interview, online learning
experts and authors Gavin Dudeney and Nicky Hockly
described their vision of European education in 2050 as
one where hybrid and flipped learning models would
become more common as collaboration replaces lecture
as the cornerstone of learning, both in the virtual and
physical realm. They emphasised the need for policy-
makersandeducatorstoworktogetherinaddressingthe
changing role of teachers and the impact of ubiquitous
technology in the classroom. While both agree that
physical learning environments are necessary for
socialisation and will likely still exist in 2050, they believe
hybrid learning models will become the mainstream for
secondary education as digital communication tools
become more sophisticated.52
Practice
Ministries of education across Europe are examining the
implications of hybrid learning for policy and practice.
The “Creative Classrooms Lab” project, for example, is
designing policies and developing capacity in support of
hybrid-based teaching and learning for nine ministries
of education, and plans to implement their ideas in 45
classrooms. The Policymaker Scenario: Flipped Classroom
envisions a classroom where teachers are expected
to guide students to resources, lead discussions, and
coordinate activities, while students are responsible
for using ICT tools to seek, organise, and prepare
information they can share with their peers during class.
After compiling observations from the pilot and making
plans for further capacity development, the project
will begin its second round of school pilots in October
2014.53

17Mid-Range Trend
In many ways, hybrid learning strategies reflect how
learning takes place in the modern workplace, and EU-
funded research teams are conceiving of new designs
for classrooms that reflect this reality. An initiative by
EuropeanSchoolnethasformaliseditsvisionsforlearning
spaces in Future Classroom Lab Learning Zones, which
are designed to optimise physical space, leverage ICT
resources,andtakeintoaccountthetransformationofthe
student-teacher role and dynamic as well as the different
learning strategies of students.54
The“Develop”scheme is
the most informal layout provided, and it is based on the
idea that independent learning is expected to take place
at home, while the classroom is used for project work and
collaborative activities. The new classroom environment
is informal and relaxed, a place where learners can use
their personal devices to access online resources and
virtual learning environments in study corners and
comfortable places, while tables and other common
areas encourage face-to-face collaboration.
Online and Blended Learning (PDF)
go.nmc.org/obl
(iNACOL, October 2013.) This publication explores
online learning policy examples from schools around
the world, sharing major trends, issues, and challenges.
Several Ministries of Education in Europe are developing
programmes to implement blended learning at scale.
> Policy
A Framework for Adopting Blended Learning in
Traditional School Based Learning
go.nmc.org/frame
(Othmanet.al.,InternationalJournalofDigitalInformation
and Wireless Communications, 2013.) Researchers from
the University of Huddersfield in the UK explain how
the ubiquity of technology is advancing a method
of learning that combines e-learning with practical,
laboratory-based learning to compose a pedagogy that
prepares learners for today’s workplace. > Leadership
Semi-AutonomousBlendedLearningforIntercultural
Communication in the Euregio Meuse-Rhine
go.nmc.org/interc
(M. Verjans and A. Gelan, European Universities’Network
on Multilingualism, accessed 6 February 2014.) Project
“INTERcCOM” seeks to simplify studying and working in
the Euregio Meuse-Rhine. E-learning modules are being
developed based on research results from studying
young Polish and Turkish natives and their language
habits to be used in either an independent learning
setting or a blended semi-autonomous setting.
> Leadership
Blended Learning in Theory and Practice: Finland
go.nmc.org/theo
(Teemu Leinonen, Media Lab Helsinki, 14 December
2013.) Elaborating on a digital first strategy, this
researcher highlights the importance of making all
aspects of a course accessible from anywhere and from
any device, so that the classroom can be repurposed as a
laboratory, studio, or workshop. > Practice
Hybrid Personal Learning Environments
go.nmc.org/bilandzic
(Mark Bilandzic, Kavasmlikon, 20 October 2013.) A
researcheranddeveloperofuser-centredmethodologies
and digital media demonstrates what a personalised,
hybrid ecosystem of learning is through the perspective
of designer and architect. > Practice
Hybridlearningmodels,
whichblendthebestofclassroom
instructionwiththebestofweb-
baseddelivery,placeastrong
emphasisonusingschooltime
forpeer-to-peercollaborationand
teacher-studentinteraction.
Hybrid learning is not unique to schools, but appears to
have more of a social component among adult learners.
A recent study published at the Eindhoven University
of Technology in the Netherlands analysed 26 informal
online communities for professional development to
find out if hybrid forms of teacher education provided
more practical benefits to teachers than other models.
Among the initial findings was that the nature of
blended learning is different with teachers than it is with
students — while students are obliged to participate
more in the virtual space, teachers tend to leverage the
blended platform to establish offline connections with
other teachers outside of their learning communities.55
For Further Reading
who wish to learn more about the increasing use of
hybrid learning and related instructional designs:

Long-RangeTrend: Driving EdTech adoption in European schools in five or more years
T
he nature of online learning has enjoyed a
renaissance over the last two years as MOOCs
have largely silenced questions about the
relevance of online learning and sparked
an explosion of development, new ideas,
and experimentation. The design of these online
experiences has become the central focus of most
discussions, and new pedagogical models and new
tools are proliferating all over the world; in Europe,
several new initiatives have been put into place
to stimulate development, notably the European
Commission’s “Opening Up Education.”56
New distance
learning offerings across the board feature more
rich media, more interactive features, better-defined
objectives and outcomes, and more polished content
than their earlier prototypes. Modernising online
learning strategies calls for the consideration of how
bothstudentsandteachersareimpacted.Studentscan
benefit from supplemental and alternative learning
experiences and teachers from online professional
development and communities of practice.
CCR Framework Element: Organisation
Overview
While the previous topic and this one are clearly related,
the ways in which online learning is evolving are much
broader than the already well-established notion of
hybridisation.This trend is expected to remain important
for some time in Europe, as the ability for schools to
support fully online learning varies considerably across
the continent. The European Commission recently
reported that 63% of the population’s nine year-
olds and 50% of 16 year-olds attend schools that are
missing important digital equipment. Twenty percent of
secondaryschoolstudentshavenever—oralmostnever
— used a computer in class. Access to online resources
is especially limited in EU countries such as Croatia and
Greece, where less than half of schools provide Internet
connectivity for students.57
Based on these gaps, the EC is working to support and
create projects that improve and expand online learning
opportunities through “Opening Up Education” and
other initiatives. This trend reflects a growing awareness
that for online learning to be a realistic option, all
aspects of school life and the school ecosystem need
to be considered. Moreover, many see online learning
as a vehicle for social equality, reaching disadvantaged
students as well as those in rural areas. The “Bednet”
in Belgium, for example, is an organisation that serves
childrenwhoaresufferingfromlong-termand/orchronic
illness.58
Similarly, the Wereldschool in the Netherlands
provides online, alternative education for students with
special needs that may not be accommodated by the
traditional school system.59
While there have been major developments in online
learning, much work remains to be done on assessment
strategies, identity management, ensuring quality,
promoting deeper student engagement, and managing
online learning at scale. The EU-funded VISCED project
has developed an online inventory of 81 virtual
schools in Europe that are promoting the use of online
learning to supplement and even replace face-to-face
schooling.60
VISCED provides case studies that analyse
the effectiveness of eight virtual schools in the EU,
detailing existing models that can be emulated, and
highlighting further work that can be done to maximise
online learning.61
These, and many related developments underway in this
arena, present schools and students with a significantly
broader range of choices for instructional delivery and
learning than has been available in the past. Several
online schools are already aimed at specific groups
of students, such as “NotSchool” in the UK, which uses
personalised learning techniques to address individual
needs.62
Practice
While there are an increasing number of online schools
and hybrid learning experiences for students, teachers
can also benefit from online continuing professional
development. Several new online initiatives expressly
target teacher education. In Spain, the Ministry of
Education developed the initiative “Formación en Red”
in order to provide teachers there with online training in
critical areas, such as open educational resources.63
The
recent launch of the European Schoolnet Academy aims
to provide better professional development for primary
and secondary school teachers, and piloted its first
courses in early 2014. These free, online courses include

19
topics such as “Innovative Practices for Engaging STEM
Teaching”and“Future Classroom Scenarios.”64
In addition to the growing array of pan-European efforts,
individual countries have assumed leadership roles in
advancing the state of online learning by producing
high-quality online methodologies and resources. For
example,theEducationDevelopmentCentreinLithuania
launched the“Development of the Key Competencies in
Basic School” project, which entailed the designing of
new online teaching approaches and materials that can
be used for language, literature, and science curriculum
for pupils in years five through eight.65
Similar efforts
are underway through the EU-funded project“Teachers’
Aids on Creating Content for Learning Environments 2”
(TACCLE2), which provides teachers with step-by-step
guides for integrating more emerging technologies
into their online learning environments for a wide range
of subjects including math, science, arts and culture,
and humanities.66
TACCLE2 also provides ideas that are
customised for specific ages.
While initiatives such as the ones mentioned above
convey a focus on expanding and improving online
learning offerings across the EU, the trend is still
perceived by many as long-range. Researchers provided
a review of online learning policy as it pertains to
European schools in an article entitled“E-learning Policy
and the ‘Transformation’ of Schooling: a UK Case Study,”
published in the European Journal of Open, Distance and
E-Learning.67
The article explored reasons why current
online education policies have not yet led to peak
effectiveness and cited difficulties encountered by more
rural countries in the EU, including lack of computer
access and insufficient ICT training for both teachers and
students necessary for the creation of and participation
in online classes.
For Further Reading
who wish to learn more about the evolution of online
learning:
EU Says School Children Lack e-Learning Facilities
go.nmc.org/eulack
(Phys Org, 25 September 2013.) Under the “Opening
Up Education” initiative, the European Commission
announced plans to fund projects that will improve
online learning in order to help learners develop more
advanced digital skills. > Policy
We Need to Close the Gap that is Swallowing Up
700,000 Kids
go.nmc.org/close
(Holly Seddon, The Huffington Post, 22 January 2014.)
There are still many students in Europe without Internet
access at home — sometimes not even in school.“Mind
the Gap”is a national programme in the UK to get every
school-age child access to online learning from home.
> Policy
How Has the Internet Changed Education?
go.nmc.org/howhas
(Sahiba Pahwa, EdTech Review, 29 May 2013.) The author
explores how the Internet has impacted education,
providing a sense of where we have been as a precursor
to how we can move forward. > Leadership
eLearning: It’s Time for a Reboot
go.nmc.org/reboo
(Carol Leaman, WIRED, 24 June 2013.) By combining
the latest technology with research on how the brain
works to improve memory and cognition, e-learning
can be modified to deliver better results. Some of these
modifications include breaking learning into bite-sized
segments and providing ongoing reinforcement of
critical points through spaced repetition. > Practice
The Impact of Technology on Curiosity
go.nmc.org/curi
(Terry Heick, TeachThought, 16 August 2013.) The
Internet has introduced an environment where students
can have an infinite number of social groups and
access large amounts of data, which has changed their
expectations for online learning experiences. > Practice
A New Pedagogy is Emerging…And Online Learning
is a Key Contributing Factor
go.nmc.org/pedag
(Contact North, accessed 6 January 2014.) This article
describes how technology and student expectations
are driving changes in pedagogy that favour knowledge
management through digital fluency and lifelong
learning skills. > Practice
Long-Range Trend
Manyseeonlinelearningasa
vehicleforsocialequality,
reachingdisadvantagedstudents
aswellasthoseinruralareas.

Rise of Data-Driven Learning and Assessment
Long-RangeTrend: Driving EdTech adoption in European schools in five or more years
T
here is an increasing interest in using new
sources of data for personalising the learning
experience, for ongoing formative assessment
of learning, and for performance measurement;
this interest is spurring the development of
a relatively new field — data-driven learning and
assessment. Learning analytics is one manifestation
of it. Learning analytics is an educational application
of web analytics, a science that is commonly used by
businesses to analyse commercial activities, identify
spending trends, and predict consumer behaviour.
Education is embarking on a similar pursuit into
data science with the aim of learner profiling, a
process of gathering and analysing large amounts
of detail about individual student interactions in
online learning activities. The goal is to build better
pedagogies, empower students to take an active part
in their learning, target at-risk student populations,
and assess factors affecting completion and student
success. For learners, educators, and researchers,
learning analytics is already starting to provide crucial
insights into student progress and interaction with
online texts, courseware, and learning environments
used to deliver instruction. Data-driven learning and
assessment will build on those early efforts.
CCR Framework Element: Assessment
Overview
Data are routinely collected, measured, and analysed in
the consumer sector to inform companies about nearly
every aspect of customer behaviour and preferences.
A number of researchers and companies are working
to design similar analytics that can reveal patterns in
learning-related data that could be used to improve
learning both for individual students, and across
institutions and systems. Before entering European
schools, many challenges will need to be addressed by
researchers and companies providing such services.
Researchers and practitioners are just beginning to
understand which data is useful for advancing learning,
as well as the scope of privacy and ethics issues. The
potential of using data to improve services, retention,
and student success is already becoming evident.
The Fischer Trust’s independent report68
on the online
platform “SAM Learning”69
details the potential of
integrating analytics in learning environments. The site
monitors student progress so that teachers can identify
and assist those having difficulty with certain materials.
The FischerTrust’s report revealed a positive relationship
between the use of the SAM Learning platform and
academic progress in General Certificate of Secondary
Education (GCSE) exams; students who used the tool
for ten hours improved their scores by one GCSE grade.
Data-driven learning can also affect the way learning is
organised in a classroom. In the Finnish upper secondary
school Martinlaakson Lukio, students participate in a
math course autonomously. Using paper materials and
formative assessment tools embedded in a learning
management system, they pace their own learning.
As a result, teachers have more time to concentrate
on students’ individual needs. This implementation of
data-driven learning not only assures that students are
learning the required content, but also teaches them
self-evaluation skills.
As the body of knowledge around learning analytics
from projects and studies continues to grow over the
next few years, school and government leaders will be
much more informed about performance measurement
statistics and how to use them to guide learning
outcomes and educational policy. Toward this end, the
EC has funded a number of research and development
projects on data-driven learning and assessment, and
adaptive learning in general. One project in this space
is “Learning Analytics Community Exchange” (LACE), a
collaborative project involving European partners who
are passionate about the opportunities afforded by
learning analytics and educational data mining.70
The
promise of data-driven learning and assessment is such
that work in this area will continue until there are easy
and efficient ways to generate and capture real-time
learning data in classrooms and schools.
Practice
In online environments especially, students and teachers
are already generating a large amount of learning-
related data from their interactions with websites,
learning software, and communication and sharing
tools that could be used to inform the learning process.
A growing number of initiatives aim to formalise
policies regarding the appropriate gathering and use

21Long-Range Trend
of student data. The EU-funded “Learning Analytics
Community Exchange”seeks to reduce risk and increase
benefit through unity of research, policy, and practice.
“Opening Up Education,” an initiative by the European
Commission, is another effort that will test the impact
of this technology on business models, and encourage
the exchange of best practices for learning analytics and
adaptive learning technologies through the Erasmus+71
and Horizon 202072
programmes, as well as through the
European Social Fund.73
A region-wide report by OECD, titled Synergies for Better
Learning: An International Perspective on Evaluation
and Assessment, suggests that data-driven evaluation
and assessment is expanding and will require more
technological sophistication at all levels of the education
system.74
To support this long-range trend, OECD
concluded that school leaders must build the capacity of
teachers to experiment with curriculum development,
improvedatacollectionskills,andunderstandcomputer-
facilitated approaches to assessment through teacher
educationprogrammes.Additionally,OECDsuggeststhe
formation of consortia and partnerships at the national
level, by providing important leadership in modelling
and disseminating best practices. To advance the use of
data-driven learning and assessment, European school
leaders can actively encourage teachers to try new
methods of assessment and find ways to generate real-
time data from classroom activities.
European schools have already started piloting online
assessment tools in hybrid classes, where teachers are
gaining experience using new forms of data. Hybrid
classes, which blend online with traditional face-to-face
class activities, present the opportunity for automated
data collection and instructional customisation. By
combining computer-based instruction with data
analysis features, teachers can track students’ progress
in the curriculum and determine how best to meet their
individual needs. Hundreds of primary and secondary
schools in Norway, the UK, and the Netherlands are
currently using the LMS, “Itslearning,”75
to facilitate this
digital strategy. The “Itslearning” platform, for example,
provides Flint High School in the UK with course
dashboards that enable both teachers and students to
get quick assessments of learning inside and outside of
the classroom.76
As more schools experiment with online
assessment tools, leaders and policy makers will have
more findings to inform the guidelines for the effective
adoption of these tools.
For Further Reading
who wish to learn more about data-driven learning and
assessment:
The Use of ICT for the Assessment of Key
Competences (PDF)
go.nmc.org/ictkey
(JRC-IPTS, 2013.) The report illuminates how ICT can en-
able assessment formats that capture students’ compe-
tencies and proposes measures needed to encourage
the development and large-scale implementation of
innovative assessments in schools. > Policy
Learning Analytics Context
go.nmc.org/lace
(LACE Project, accessed 6 February 2014.) LACE is a
collaborative project involving European partners who
are passionate about the opportunities afforded by
learning analytics and educational data mining.
> Leadership
The Potential of Learning Analytics and Big Data
go.nmc.org/poten
(Patricia Charlton et al., Ariadne, 8 July 2013.) The UK
authors believe that gaining access to data is not the
problem; instead, determining which data are significant
and why is the challenge. > Leadership
AssessmentStrategyatMartinlaaksonLukio
go.nmc.org/marti
(Pekka Peura, Matematiikan Opetuksen Tulevaisuss, 12
February 2014.) At Finnish upper secondary school
Martinlaakson Lukio, students use their own learning
data to self-assess in order to advance through the
course. The method is based on Bloom’s mastery
learning model and it bypasses the need for final exams.
> Practice
Formative Assessment and Learning Analytics (PDF)
go.nmc.org/format
(DirkT.Tempelaaretal.,UniversiteitvanAmsterdam,April
2013.) This paper from researchers in the Netherlands
examines what individualised information feedback can
look like in a blended learning environment. > Practice
Khan Academy’s Use of Data to Assess Learning
(Video)
go.nmc.org/assess
(Geddes Munson, YouTube, 25 March 2013.) This video
entails a description of what comprises Khan Academy’s
analytics model: thoughtful measurement of learning,
user goals, game mechanics, and machine learning with
the support of researchers. > Practice

Challenges Impeding Educational Technology Adoption
in European Schools
T
he six challenges described on the following
pages were selected by the project’s expert panel
in a series of Delphi-based cycles of discussion,
refinement, and voting; the expert panel was
in consensus that each is very likely to impede
the adoption of one or more new technologies if
unresolved. A complete record of the discussions and
related materials were captured in the online work site
used by the expert panel and archived at europe.wiki.
nmc.org/Challenges.
Because not all challenges are of the same scope, the
discussionsherearesortedintothreecategoriesdefined
by the nature of the challenge. The Horizon Project
defines solvable challenges as those that we both
understand and know how to solve; difficult challenges
are ones that are more or less well-understood but for
which solutions remain elusive; and wicked challenges,
the most difficult, are categorised as complex to even
define, and thus require additional data and insights
before solutions will even be possible. Once the list
of challenges was identified, the “Upscaling Creative
Classrooms in Europe” (CCR) framework, detailed in
the Executive Summary, served as a lens to identify
implications for policy, leadership, and practice.
The CCR Framework places learning environments,
wherever they may occur, as part of an ecosystem
that evolves over time, and that is very responsive
to the context and culture in which they reside. The
eight-dimensional framework is systemic by nature,
and encourages the design of multi-dimensional
approaches when scaling up innovative pedagogical
practices, especially in ICT-enabled learning settings.77
The NMC Horizon Project model derived three meta-
dimensions from the CCR framework that were used to
focusthediscussionsofeachtrendandchallenge:policy,
leadership, and practice. Policy, in this context, refers to
the formal laws, regulations, rules, and guidelines that
govern schools; leadership is the product of experts’
visions of the future of learning, based on research and
deep consideration; and practice is where new ideas
and pedagogies take action, in schools, classrooms, and
related settings.
Policy. While all of the identified challenges have
important policy implications, two specific challenges
are driving policy decisions in European schools at
the moment. The easiest of these to address is the
development of and adoption of policies related to
enhancing the digital competence of students. The
work to frame such policies is already well underway
in the European Commission, which published a recent
report with a digital competence framework that can
serve as a meta-framework for current frameworks,
initiatives, curricula and certifications.78
The framework
has been endorsed by EU Member State representatives
Thematic Working Group on ICT and Education. Several
Member States are already trying out the framework
as a comprehensive approach to identify, describe and
assess digital competence.
Becausenotallchallenges
areofthesamescope,
thediscussionsherearesorted
intothreecategoriesdefined
bythenatureofthechallenge.
Still a few years away from being solved is the challenge
of blending non-formal and formal learning approaches
into a comprehensive model of learning. Policymakers
have been relatively quiet in terms of developing
guidelines that connect this kind of learning with
formal curriculum, but the Slovenian government has
been developing standards and criteria. As part of their
Vocational Education and Training programme, they
aim to better define informal experiences so they may
be included as part of special vocational pathways.79
Leadership. Leadership implications are common
to all the challenges described in this section, but two
will require visionary leadership. The first is considered
by the expert panel as an urgent need to address the
lack of ICT education for teachers. Fifteen ministries
of education in Europe have formally recognised this
challenge and are partnering with European Schoolnet

23
on their“iTEC: Designing the Future Classroom”project.
Through this initiative, more in-service and pre-service
teachersarelearninghowtoeffectivelyapplyICTintheir
classrooms from pedagogical and technical trainers.80
The second opportunity for extraordinary leadership
was deemed a wicked challenge by the expert panel.
Schools are trying to understand how to include
students in the design of learning experiences, even as
personalised learning, the flipped classroom, and other
forward-thinking approaches are already shifting more
control over learning to students. The inability to define
this challenge combined with a lack of clear strategies to
solve it is what makes it wicked.
Practice. Each of the six challenges identified by
the expert panel presents numerous impediments for
advancing teaching and learning, and two are viewed
as particularly daunting to solve. Incorporating more
authentic learning in curricula is classified as a difficult
challenge, but it is already a priority for many schools
in Europe, including the Marina Laroverket School in
Sweden. In their immersive learning model, they invite
students to study aboard a sailboat over the course of a
monthandimmersethemselvesinpracticalapplications
of astronomy and marine biology in the field.81
Many educational leaders and theoreticians feel that
the research required to understand complex thinking
and communication is just beginning to produce new
insights — making it a wicked challenge. Until that
happens, it will be all but impossible to deploy new
models that will integrate these skills into classroom
activities. Nonetheless, the expert panel felt that these
skills are critical if we are to develop the scientists,
engineers, and leaders that are needed to address the
global challenges students will face.
The following pages provide a discussion of each of
the challenges highlighted by the expert panel that
includes an overview of the challenge, its implications,
and curated recommendations for further reading on
the topic.
Challenges

Integrating ICT in Teacher Education
Solvable Challenge:Those that we understand and know how to solve
T
he Survey of Schools: ICT in Education report82
found that ICT is not being used to its full
capacity across the European Union. While the
majority of schools are connected and equipped
with technology, many teachers lack the skills
or formal education they need to empower learners
to pursue their own interests and free class time for
moreexperientialformsoflearning.There is a need for
teacher education programmes that integrate digital
pedagogies and learning in a way that is not merely
superficial, but founded on the meaningful research
that shows how students best learn with digital tools
and methods. Many of these emergent methods
support environments where the Internet and web-
based applications offer a way for learners to explore,
create, and share knowledge with each other.
CCR Framework Element: Leadership & Values
Overview
Thelackofadequateteachereducationrelatingtodigital
learning and digital pedagogies is a challenge that is
widely acknowledged and documented throughout
Europe. A number of countries are working to update
their teacher education programmes to include
techniques and strategies for digital learning, but there
is still much to be done.83
ICT training comprises a
component of initial teacher education in just over half
of EU countries, but implementation varies by institution
and country. The challenge for pre-service teachers
is that although ICT is deemed important, it is not a
compulsory component for all initial teacher education
programmes. A majority of the training currently
available to in-service teachers focuses primarily on
learning software, and much less on integrating ICT into
instruction in ways that add real value to learning.
The Survey of Schools: ICT in Education identified
several obstacles that are all too often present when
implementing ICT in the classroom, ranging from
insufficient ICT equipment for digital learning, lack of
competence and pedagogical models, unclear goals
for using ICT or lack of consensus about what the
goals are, and the lack of mandatory teacher training
in ICT.84
Additionally, the study revealed that although
there are many online opportunities for teachers,
they look for professional development online only
a minority of the time. A recent TALIS survey by OECD
supports these findings; the research shows that on
average, 65% of TALIS teachers reported that their
ICT training used traditional forms of expert-led
workshops or seminar-style classes.85
The TALIS study
also illuminated impediments such as conflicts with
teachers’work schedules and a general feeling that there
was no suitable professional development available.
Professional learning communities could be the key to
addressing many of these obstacles by providing school-
wide, ongoing support for teacher ICT education.
Technology already permeates almost every dimension
of students’ and teachers’ lives outside of school, and
both students and their parents expect schools to help
them to become fully competent digitally. A wide range
of pedagogies and strategies exist for instilling fluency in
technology; many are even mapped for use in a range of
specific disciplines. Further demonstrating the need for
this dimension of teacher preparation to be enhanced,
the Norwegian SMILE report86
and Survey of Schools: ICT
in Education found that the uneven pedagogical use of
technology in the classroom revolves around a number
of factors, but the most important finding is that the
level of a teacher’s digital competence directly correlates
with students’ learning outcomes when technology is
used.
Practice
One of the reasons this challenge is perceived as
solvable is that the challenge is well understood,
and solutions are available. As Survey of Schools: ICT
in Education documented, for example, teachers
are not taking advantage of formal teacher training
opportunities that exist, and are using ICT primarily to
prepare their teaching instead of having students use
technology in their work. The report recommends the
creation of policies to boost the development of digitally
supportive schools and teachers by promoting the use
and integration of ICT in the classroom and investing
in capacity building for in-service teacher education.
Many education leaders agree — to ensure schools
and teachers are able to deliver on the expectations of
parents, employers, and society, digital learning should
permeate teacher education at all levels.

25
University pre-service programs are also beginning to
see the importance of their leadership and willingness
to innovate if this challenge is to be met, and some
are stepping up with new programs aimed directly at
the issue. The Universidad Pablo de Olavide in Spain,
for example, has developed the “New Information
Technologies and Communication” module for
teachers of secondary education students.87
Among
the objectives of this training module are to promote
the active and independent role of students in the
process of knowledge construction and design, to
develop interactive concept maps about the strengths
and weakness of ICT in educational contexts, and to
encouragemultimodallearning.Themoduleisorganised
in several thematic clusters: society, education, and ICT;
students and teachers of the new millennium; social
software and example of good practice with ICT; and
the study of educational platforms and evaluation of
multimedia network materials.
In-service teachers looking to learn more about effective
use of ICT in the classroom can turn to the growing
array of resources across Europe aimed precisely at
this need. “Edukata,” for example, enables Finnish in-
service teachers to turn their innovative ideas into actual
classroom practice.88
They do so by investigating digital
scenarios such as BYOD, the flipped classroom, or online
learning,andcreatingfutureclassroomlearningactivities
that reflect key aspects of the personal interests and
needs of their students. Similarly, European Schoolnet’s
Academy provides free online teacher training in key
ICT concepts and ideas and enables practicing teachers
to share their experiences with their colleagues across
Europe. Two pilot courses include “Future Classroom
Scenarios” and “Innovative Practices for Engaging STEM
Teaching.”89
For Further Reading
who wish to learn more about integrating ICT in teacher
education:
The‘Teacher Effect’on the Use of ICT
go.nmc.org/schoolnet
(European Commission, April 2013.) The Survey of
Schools: ICT in Education found that about half of
European students are taught by teachers that are
confident with using ICT in the classroom, but only a
fraction of those teachers have access to technology in
their schools and ICT training. > Policy
Teachers Need Confidence to Teach Coding Properly
go.nmc.org/conf
(Andrew Manches, The Conversation, 24 January 2014.)
The author argues that there is insufficient research into
what makes good coding pedagogy and digital literacy
because it is often not incorporated in teacher training.
> Policy
Eduvista
go.nmc.org/eduvista
(Eduvista, accessed 6 February 2014.) The “Eduvista”
toolkit helps teachers organise their educational visions
through change management and helping stakeholders
and ICT experts better understand schools’needs.
> Leadership
Hands-On ICT: Learn, Practice, Teach Creativity and
ICT
go.nmc.org/handson
(Hands-On ICT, 25 March 2013.) The “Hands-On ICT”
project, funded by the Lifelong Learning Programme
of the EC, facilitates the integration of ICT tools in
education by employing a learn-by-doing model in
which teachers learn on their own with the support of
mentors. > Leadership
Adopting Digital Skills in an International Project in
Teacher Education
go.nmc.org/nordseth
(Hugo Nordseth, International Journal of Media,
Technology, and Lifelong Learning, 2012.) An associate
professor describes a project to train teachers using ICT
tools and video-based learning resources, as well as to
coordinate collaborative work. > Practice
Education Researcher to Teachers: Use Available
Technology to Improve Student Achievement
go.nmc.org/learnblend
(Mark Macdonald, Itslearning, 17 September 2013.) The
head of Digital Learning Communities at the University
of Bergen in Norway believes teachers need to adopt
ICT tools because they offer learners different ways to
demonstrate content mastery. > Practice
Solvable Challenge
In-serviceteacherslooking
tolearnmoreabouteffective
useofICTintheclassroom
canturntothegrowingarray
ofresourcesacrossEurope
aimedpreciselyatthisneed.

Students’Low Digital Competence
Solvable Challenge:Those that we understand and know how to solve
D
espite a range of national and pan-European
digital competence initiatives, research from
sources such as the “EU Kids Online”90
project
shows that the levels of digital competence in
children and teenagers remain inadequate,
especially on the dimensions of critical and
participatory literacy, where students do not just read
content, but also engage with it and actively create
their own responses to it. In an age when news often
spreads virally through social media, most experts feel
itiscriticalthatyoungpeoplelearnhowtoanalyseand
evaluate the authenticity of the myriad of messages
they encounter everyday.
Overview
The EU has defined digital competence to be the
confident, critical, and creative use of ICT to achieve
goals related to work, employability, learning, leisure,
inclusion and/or participation in society. All EU Member
States agree that digital competence education is a
means for learners to hone their skills for productivity
and the creation and understanding of media.91
While
many European countries have established digital
competence programmes for students in the past
decade, there is a continuing need to update learning
outcomes and objectives to adapt to the current
technological terrain. Education policy is continuously
challenged to stay abreast of the evolution of media
and the devices used to access it, and increasingly,
digital competence of students is not just the focus of
educators, but also policymakers and regulatory bodies,
as well as media-oriented NGOs and citizen initiatives.
Since 2006, the “EU Kids Online” project has been
actively monitoring research about the benefits and
risks that youth may encounter while engaging in online
activities.92
They have charted the understanding of how
children use online technologies and have identified
several significant gaps in research around online
activity. These include uneven coverage by age, an
overwhelming focus on the fixed Internet (to the neglect
of mobile, convergent, and emerging technologies), the
roles of parents and teachers, and safety mediation.
Improving the abilities of students to interpret and
create digital media is a problem that is understandable
and solvable; much is known about the topic, both at the
policy and practice levels. Teacher education will be at
the centre of successful solutions. To prepare European
students for the skills and capacities for 21st century
citizenship — global awareness, creativity, collaborative
problem-solving, and self-directed learning — it is clear
that the core practice of teaching and learning must
include the tools and resources used commonly by most
of the population.
Practice
The DIGCOMP project, released in 2013 by the European
Commission, was part of a multi-year policy effort
initiated by DG EAC and executed by JRC-IPTS to define
digital competence in order to establish an umbrella for
frameworks, curricula, and certifications in this area.93
The project identified the key components of digital
competence in terms of knowledge, skills, and attitudes;
developed descriptors to inform a conceptual framework
and/or guidelines; and proposed a roadmap for a digital
competence framework. The authors defined digital
competence needs as including the following areas:
information, communication, content-creation, safety,
and problem solving. Each of these areas was placed
in a matrix and included a general description of the
competence; descriptors on three proficiency levels;
examplesofknowledge,attitudes,andskills;andexamples
of applicability for different purposes. The framework has
been endorsed by EU Member States representatives
Thematic Working Group on ICT and Education and
several Member States are already using it.
The European Commission’s “Opening Up Education”
initiative includes a comprehensive effort to solve
identified deficiencies in digital competence and
provide schools with the framework and tools necessary
to prepare students for jobs in the growing European
digital economy.94
Indeed, the EC has projected that
by 2020, 90% of European jobs will require digital
skills. Three key initiatives have been identified as
strategies to improve digital competence: encourage
teachers and educational institutions to test innovative
digital approaches; ensure open access to educational
materials; and improve the digital infrastructures of

27Solvable Challenge
schools. Support for these initiatives will come from the
new programmes Erasmus+95
and Horizon 2020,96
as
well as through the European Social Fund.97
TheEU-fundedprojectiTECinvestigateshowestablished
and emerging technologies can be used effectively
in classrooms over the next several years.98
As part of
the initiative, the ORT School in Milan will implement
iTEC’s “Design of the Future Classroom” model.99
In this
comprehensive digital competence project, a class of 15
year-old students will utilise collaborative video-making,
a flipped classroom methodology, and Edmodo social
media technology to develop video math tutorials for
younger students. Findings from the first three years
of the iTEC project have revealed a positive impact
on students’ knowledge, skills, and learning practices
as well as improving teachers’ technology-supported
pedagogy, digital competence, and motivation.
DIYLab Do It Yourself in Education: Expanding
Digital Competence to Foster Student Agency And
Collaborative Learning
go.nmc.org/diyl
(European Commission, Education, Audiovisual and
Culture Executive Agency, 6 March 2014.) A 3-year
project called DIYLab, coordinated by the University
of Barcelona, Charles University in Prague, Escola
Virolai, and ZŠ Korunovační, explores the educational
intersection of technology, digital media, and the
creative DIY culture. > Leadership
EU Kids Online III: A Thematic Network to Stimulate
and Coordinate Investigation into the Use of New
Media by Children (PDF)
go.nmc.org/euk
(The London School of Economics and Political Science,
31 October 2013.)The“EU Kids Online”network provides
findings and critical analyses of new media applications
and associated risks among children across Europe in an
effort to sustain an active dialogue with stakeholders
about priority areas of concern for child online safety.
> Leadership
Vassiliou Calls for More Focus on Media Literacy
go.nmc.org/vassiliou
(European Commission, 18 October 2013.)The European
Commissioner for Education, Culture, Multilingualism,
and Youth acknowledges the need for children to begin
studying media and communication, as it is considered
an essential competence in the European economy.
> Leadership
A Journey to Media Literacy (Video)
go.nmc.org/eavi
(EAVI, 29 January 2013.) This animation from the
European Association for Viewers Interests provides an
explanation of media literacy and why it is important for
youth to be able to evaluate, understand, and produce
audio-visual media and communications. > Practice
Learning to Be: Developing and Understanding
Digital Competence (PDF)
go.nmc.org/devel
(Morten Søby, idunn.no, 2013.) The author argues that
schools must equip youth with the necessary digital
skills that will allow them to cope with the challenges
that fostering connectedness poses, and therefore
students need digitally competent teachers as role
models. > Practice
WhilemanyEuropeancountries
haveestablisheddigital
competenceprogrammesfor
studentsinthepastdecade,
thereisacontinuingneedto
updatelearningoutcomesand
objectivestoadapttothe
currenttechnologicalterrain.
For Further Reading
who wish to learn more about students’ low digital
competence:
DIGCOMP: A Framework for Developing and
Understanding Digital Competence in Europe (PDF)
go.nmc.org/digc
(JRC-IPTS, 2013.) This report details the various aspects
of digital competence by listing 21 competences and
describing them in terms of knowledge, skills, and
attitudes. It then proposes a framework for digital
competence. > Policy

Blending of Formal and Non-Formal Learning
Difficult Challenge:Those that we understand but for which solutions are elusive
T
here is increased focus on the kinds of self-
directed, curiosity-based learning that can
happen in non-traditional, non-formal
educationalenvironments,especiallyasaccessto
ICTtoolsexpandsthroughoutEurope.Museums,
libraries, and science centres have historically been
hubs for non-formal learning, and now commonly
incorporate digital resources into their programming
and encourage visitors to delve deeper into subject
matter via their mobile devices. As more Europeans
are able to connect to the Internet and pursue inquiries
at their leisure from wherever they choose, there is a
burgeoning discussion about formalising these types
of educational experiences. While some EU Member
States have made significant progress on qualifying
non-formal learning for adults through VET programs,
there is mounting effort to recognise the value of non-
formal and informal learning for European youth
as well. Many experts believe that the promise of
blending outside learning experiences into formal
education will create a dynamic environment that
fosters experimentation, curiosity, and creativity and,
perhaps most importantly, a propensity for learning
that will endure throughout a student’s lifetime.
CCR Framework Element: Assessment
Overview
The blending of non-formal learning into formal
education is an intriguing notion, but hampered by the
lack of ways to acknowledge and qualify learning that
happens beyond the classroom. Adding complexity
to the matter is a lack of clear ways to quantify the
kinds of informal learning experiences in which youth
engage. Some argue that in order to integrate non-
formal education into the formal system, skills that have
tangible, transferable value in the real world must be
identified and promoted as key competences. Much
work has been done to define and explore those aspects
of non-formal learning, but the larger frame of possible
learning — now generally understood as the kinds of
acquisition of knowledge that occur in everyday life
but are not usually formally evaluated — is not so well
understood.
In 2010, OECD worked with representatives from 22
countries to compile their experiences in a report
entitled Recognising Non-Formal and Informal Learning,
which provides a foundation for countries to begin
defining learning and skills that are gained outside
of formal institutions.111
The overall goal of this work
is a massive undertaking — to be able to accurately
assess human capital within a nation with the aim of
strengthening all economies involved. At a time when
many EU Member States are faced with high levels of
youth unemployment, the need to continue this effort
for young people has become a high priority.112
As
access to ICT tools and the Internet steadily increase,
there are more opportunities for European youth to have
profoundlearningexperiencesininformalenvironments
and to pursue employable skills on their own.
As other non-formal learning institutions such as
museums, libraries, and science centres are exploring
the potential of ICT to engage their patrons, activities
offered to the public are growing more sophisticated,
providing opportunities for people to gain real-world
skills. A recent EU-funded initiative offers European
youth authentic STEM experiences through “SciCamp,”
a network of European institutions and organisations
that provide programming for students to explore
science and technology using inquiry-based learning
and ICT.113
“SciCamp” connects learners with role
models in the field by establishing relationships for
students with local companies and laboratories, as
well as regional universities, technical universities, and
other STEM-focused institutions. In a similar vein, the
London Science Museum’s “Robot Safari” exhibition
featured 13 biomimetic robots along with their makers
who explained how they were used to study plant and
animal behaviours. As part of the three-day exhibition,
participants learned to program, build, and race their
own simple robots through a series of interactive
workshops.114
Practice
Work is well underway across Europe to develop policies
to guide the validation of non-formal and informal
learning. The Council of the European Union recently
released their official recommendation that by 2018,
MemberStatesshouldhavearrangementstovalidatethis
type of learning through the processes of identification,
documentation, assessment and certification.115
Since

29Difficult Challenge
2004, the European Commission has been consulting
stakeholders, teachers, students, and human resource
managers for the European Inventory Project, a
compilation of best practices and relevant legislation
from over 30 Member States that is updated constantly.
Slated to release in late 2014, the latest edition of the
European Inventory Project will inform policymakers of
systems that have already proven effective as they work
toward achieving this benchmark.116
EU-funded initiatives in the museum sector are
highlighting the array of quality educational experiences
offered by cultural institutions across the EU with the
aim of legitimising informal learning. The Learning
Museum, for example, is a network of 23 partners from
Europe and the United States that are working on how
museums can and should play an active role in support
of lifelong learning. The organisation’s website provides
a place where museum stakeholders can contribute to
discussion on the recognition of skills and qualifications
of learners and workers, as well as share descriptions of
summer schools, camps, free online courses, and other
activities that promote non-formal and informal learning
activities for children and adults.117
Building frameworks for assessment is a key piece of
the solution, as schools and teachers will need criteria
to measure non-formal experiences in ways that are
transparent and transferable across borders. The Youth
on the Move programme, Youth Pass, for example,
legitimises learning outcomes for youth that participate
in voluntary service, training courses, or work exchanges,
and awards certificates that list the key competences
acquired by the participant. While Youth Pass is not
integrated in the formal education system, it is a method
that has successfully promoted key Lifelong Learning
competences, and can serve as one model for assessing
non-formal experiences for youth.118
For Further Reading
who wish to learn more about the blending of formal
and non-formal learning:
Council Recommendation on the Validation of Non-
formal and Informal Learning (PDF)
go.nmc.org/valid
(The Council of the European Union, Official Journal of
the European Union, 20 December 2012.) As a response
to a proposal from the European Commission, the
Council of the EU makes recommendations on how to
proceed with the integration of non-formal learning into
formal learning scenarios. > Policy
Potential and Perspective of Non-Formal Education
for the Future of the Younger Generation
go.nmc.org/potential
(Justina Vitkauskaite Bernard, The Baltic Times, 28
November 2013.) A Lithuanian member of the European
Parliament describes an innovative approach that
encourages youth to be lifelong learners who use
technologytolearnnon-formally,withtheaimofgaining
the competences and skills they need for employment.
> Policy
Informal Learning: Facing the Inevitable and Seizing
the Advantage
go.nmc.org/inevitable
(Terry Heick, Edutopia, 7 March 2014.) The author makes
the case that educators can no longer afford to resist
the cultural and technological trends that have already
disrupted how people access information, connect with
one another, and publish the events of their lives.
> Leadership
Designing Blended Learning Space to the Student
Experience
go.nmc.org/space
(Andrew J. Milne, EDUCAUSE, accessed 1 April 2014.)
The authors highlight a shift in learning to more social,
non-formal, and less structured activity. He visualises
classrooms designed as meeting spaces that facilitate
interaction and collaboration. > Practice
LearningWhy Ships Float at the Lithuanian Sea
Museum
go.nmc.org/ships
(Creative Classes Laboratory, 13 December 2013.) Year
seven students visited the Lithuanian Sea Museum to
get hands-on experience with buoyancy by performing
their own experiments to learn how vessels float.
> Practice
Opportunities via Extended Networks for Teens’
Informal Learning (PDF)
go.nmc.org/exte
(Peyina Lin and Shelly D. Farnham, ACM 2013.) Interviews
with secondary school students explore their non-formal
learning activities, what contributes to their initiation
and continuation, and the role of technologies for their
non-formal learning. > Practice

Creating Authentic Learning Opportunities
Difficult Challenge:Those that we understand but for which solutions are elusive
A
uthenticlearning,especiallythatwhichbrings
real life experiences into the classroom, is
still all too uncommon in European schools.
Authentic learning is seen as an important
pedagogical strategy, with great potential
to increase the engagement of students who are
seeking some connection between the world as they
knowitexistsoutsideofschool,andtheirexperiences
in school that are meant to prepare them for that
world. Use of learning scenarios that incorporate
real life experiences, technology, and tools that are
already familiar to students, and interactions from
community members are examples of approaches
that can bring authentic learning into the classroom.
Practices such as these may help retain students
in school and prepare them for further education,
careers, and citizenship in a way that traditional
practices are too often failing to do.
CCR Framework Element: Content & Curricula
Overview
Authentic learning, as defined by the EDUCAUSE
Learning Initiative, typically focuses on real-world,
complex problems and their solutions, using role-
playing exercises, problem-based activities, case
studies, and participation in virtual communities of
practice. EDUCAUSE’s report Authentic Learning for
the 21st Century: An Overview suggests that authentic
learning prepares students for the skills and knowledge
demanded by universities and the workplace.100
Experiential and hands-on learning curricula represent
early efforts, but much remains to be done, including the
design of methods to assess these activities. Establishing
mutually beneficial relationships with businesses,
organisations, and public entities in the community
is seen as a promising avenue for development, but
effective models are rare. Very few schools have forged
these kinds of relationships. Fewer still are teachers
who are adept in the design and delivery of authentic
learning approaches.
While the concepts inherent in authentic learning
are appropriate for many disciplines, the need for
authenticity is expressed most often in science,
technology, and mathematics education. Across
Europe, there has been a marked decrease in students
pursuing science degrees in college, a trend that is
already creating a shortage of qualified workers for the
science and technology industries. As a result, there is a
growing focus on the need for students to experience
what the work of real scientists is like. Authentic learning
focuses on involving students in citizen science projects
and other activities that can bring science to life.
Online citizen science projects such as “Zooniverse,”101
“CamClickr,”102
and “Evolution MegaLab”103
allow
students to participate in authentic scientific discovery.
In each of these examples, students can contribute real
data and observations about their surroundings to a
growing database. “Evolution MegaLab,” for instance,
encourages students to study the evolution of the
banded snail by recording observations of snails in their
community as part of a massive project to understand
the evolution of snail shell colouring.
“Virtual Enterprises International” is an example of how
authentic learning experiences can connect students
with the world of business and entrepreneurship,
preparing them for continuing their education and
entering the workforce.104
This in-school, global
business simulation offers students project-based and
collaborative learning, along with the development of
21st century skills in areas including problem-solving,
communication, personal finance, and technology.
Inspired by the Austrian model of apprenticeships,
this experiential learning model engages students
by replicating all the functions of real business in
both structure and practice. Teacher-facilitators and
business mentors guide students as they create and
manage all facets of their virtual business from product
development to marketing in a range of firms.
Practice
While many educators are embracing the concept
of authentic learning, there is a need for concrete
policies that will stimulate the interest of schools and
help guide them throughout the process — from
standards for defining and evaluating authentic learning
to establishing safety protocol for offsite learning
experiences. Many current examples of authentic
learning in practice involve initial vocational education,
in which upper secondary students are undertaking
apprenticeships and shadowing professionals at local

31Difficult Challenge
enterprises. The European Commission’s report, Work-
Based Learning in Europe, assesses the state of these
programmes and makes education and labour market
policy recommendations to maximise their safety and
effectiveness.105
Among other suggestions, the report
calls for investing in other types of work-based learning,
includingthedevelopmentofonsitelabsandworkshops
in schools that link back to the offsite vocational training.
In order to facilitate authentic learning in their
classrooms, teachers will need adequate support
to update their pedagogies and teaching materials.
ESTABLISH (“European Science andTechnology in Action
Building Links with Industry, Schools, and Home”) is
an EU-funded project in which policymakers, parent
groups, and others are coming together to develop
authentic learning experiences for secondary students,
while providing education programmes for teachers
to help them incorporate this new curriculum in their
classrooms.106
Similarly, the “Developing Real World
Authentic Learning” project, co-funded by the Republic
of Cyprus and the European Regional Development
Fund, developed its own model of authentic learning,
based on real-world problem-solving through
collaborations between schools and enterprises.107
The
project includes training programmes for teachers as
well as online instructional materials that support staff
capacity-building. Standards of assessing authentic
learning experiences are not yet readily available.
While projects such as ESTABLISH convey an active
interest from EU leaders to implement authentic
learning in STEM areas, more leadership is needed by
EU Member States and the local educational authorities
across all primary and secondary school disciplines.
3D printing is being viewed as a way to achieve more
hands-on learning in the humanities, allowing students
to explore cultural history through replicas of real-world
artefacts. Greek company Museotechniki recently won
an award from the EU @Diversity Ideas Competition for
their 3D printing project “Museofabber.”108
The project
aims to open up access to museums’ digital collections,
so that schools can print historical objects for teaching
and learning. Increasingly, leaders are looking to
facilitate similar activities on school grounds in the
form of makerspaces. These designated spaces enable
students to tinker, experiment, and build with tools such
as 3D printers, laser cutters, and microcontrollers. Most
schools in Europe do not yet have onsite makerspaces,
but there is an opportunity for leaders to partner with
organisations like MakerFaire Rome109
or Barcelona’s
MADE Makerspace,110
and strategise ways to develop
them in schools and school libraries.
For Further Reading
who wish to learn more about authentic learning:
Germany’s Unique Key to Success
go.nmc.org/unique
(Stefan von Borstel, Press Europ, 8 May 2013.) Germany’s
dual vocational training system has enabled more real-
world learning, decreased their unemployment rate
dramatically, and now supply outweighs demand.
> Policy
The inGenious Code: School - Industry Collaboration
go.nmc.org/inge
(Jean-Noel Colin et al., European Schoolnet, June 2013.)
Collaboration between school and industry is becoming
more common in Europe to help students gain real-
life perspectives, especially on how STEM subjects are
applied in research and business. The inGenious code of
conduct is Europe’s ﬁrst attempt to guide both schools
and businesses in forming alliances. > Policy
Robotics Lessons in New Curriculum
go.nmc.org/robot
(Graeme Paton, Education News, 7 July 2013.) Children
as young as five years-old will be learning about robots,
programming, 3D printers, and laser cutters after the
UK government mandated that the national design
and technology syllabus be revised to teach more
engineering-related skills. > Policy
A Hands-On Approach to Physics in the Classroom
go.nmc.org/phot
(European Commission: Horizon 2020, 13 December
2013.) A team of photonics researchers, teachers, and
experts in pedagogy from 11 EU countries has created
a new educational kit with equipment for fun classroom
experiments to be distributed free to schools across
Europe. > Leadership
Is it Project-Based Learning, Maker Education or Just
Projects?
go.nmc.org/pbledu
(Jackie Gerstein, User Generated Education, 22 October
2013.) The author believes that many attempts to
implement authentic learning experiences fail because
teachers lack a solid foundation in the concept. She
shares a list of guiding questions for educators. > Practice
Why Academic Teaching Doesn’t Help Kids Excel in
Life
go.nmc.org/excel
(Shelley Wright, Mindshift, 14 November 2013.) An
educator describes how she transformed her instruction
to move away from its traditional academic focus and
into a project-based, technology-enhanced pedagogy
that mimics real world scenarios. > Practice

Wicked Challenge:Those that are complex to even define, much less address
I
t is essential for schoolchildren both to understand
the networked world in which they are growing up
and also — through computational thinking — to
understand the difference between human and
artificial intelligence, learn how to use abstraction
and decomposition when tackling complex tasks, and
deployheuristicreasoningtocomplexproblems.119
The
semantic web, big data, modelling technologies, and
other innovations make new approaches to training
learnersincomplexandsystemsthinkingpossible.Yet,
mastering modes of complex thinking does not make
an impact in isolation; communication skills must
also be mastered for complex thinking to be applied
in profound ways. Indeed, the most effective leaders
are outstanding communicators with a high level of
social intelligence; their capacity to connect people
with other people, using technologies to collaborate
and leveraging data to support their ideas, requires an
ability to understand the bigger picture and to make
appeals that are based on logic, data, and instinct.
Overview
While some aspects of this topic could be framed as
similar to or overlapping with what several authors
have described as “design thinking,” for the purposes of
this report, the two are considered as distinct concepts.
The term “complex thinking” refers in this report to the
ability to understand complexity, a skill that is needed
to understand how systems work in order to solve
problems.120
Complex thinking could be described as
an application of systems thinking, as the ability to
decipher how individual components work together as
part of a whole, dynamic unit that creates patterns over
time is very much a part of this idea.121
Computational thinking, too, relates to the notion of
complex thinking. Computational thinking entails
logical analysis and organisation of data; modelling,
abstractions, and simulations; and identifying, testing,
and implementing possible solutions.122
Emphasis
on these approaches in education helps learners
understand how the world works and equips them with
skills deemed essential in solving complex problems.The
third leg of the stool is the ability to make complex ideas
understandable, using data visualisation, new forms of
imagery, succinct narrative, and other communications
tools. In today’s world, it is not enough to be able to
conceptualise difficult challenges — one must also be
able to make those ideas easy to grasp, easy to share,
and easy to support.
Companies like Amazon, Google, and Facebook have
been built on the insights of complex thinkers and
communicators, who have popularised the use of big
data to capture user-derived data in real-time, redefined
the way we conceptualise consumer behaviour, and
have built entirely new businesses based on this work.
These skills can be applied across virtually any industry,
but schools are not yet adept at encouraging greater
development of complex thinking and communication.
According to the European Commission’s report, Big
Data: Analytics & Decision Making, the market demand
for big data is currently estimated at over €56 billion,
and it is growing by 10% every year.123
A recent report by
business analytics provider, SAS, found that demand for
data specialists is expected to rise by 243% over the next
five years in the UK alone.124
If data science is expected to
become a major standard for decision-making, schools
will be expected to shape learners who have complex
thinking skills, and can use data and visualisations to
support their reasoning.
Practice
Policy makers in the EU are aware that big data is rapidly
becoming the model for productivity and have included
it in the Digital Agenda of the Europe 2020 Initiative.
EURYDICE conducted the latest comprehensive survey
of European national policies, research, and practices in
science education in 2011.125
Their findings noted that
although there were many countries with individual
programmes to promote data science education, few
operated under the guidance of well-defined national
strategies. While countries such as Germany, Spain,
Ireland, the Netherlands, the United Kingdom, and
Norway have STEM education plans in place, initiatives
that focus on introducing data science and other
21st skills to young learners are rare. This is changing,
however, as countries such as the UK and Estonia have
made computer programming part of their national
curricula.126

33Wicked Challenge
Leaders seeking to foster complex communication skills
in schools can refer to programmes that have already
been scaled and proven effective. A good example is the
EU-funded “Promoting Social Skills amongst Students”
(PSS) project.127
This initiative brought together
institutions from five European countries — Bulgaria,
Denmark, Italy, Poland, and the UK — with the intention
of producing educational materials that promote
effective communication skills such as understanding
social cues, listening to the thoughts and feelings of
others, and negotiating with others who have differing
viewpoints. PSS created a guide with 60 lesson plans that
reinforce social intelligence through games, discussion,
and group tasks targeted at students ages 14 and up.
Practitioners can include more problem-solving and
collaborativeworkattheclassroomlevel.Inarecentstudy
of a post-primary mathematics class in Ireland, teacher
Caitriona Rooney describes her success with inquiry-
based learning (IBL) as a catalyst for complex thinking.128
Rooney concluded that not only does IBL foster higher-
order thinking, but the model also encouraged her
students to take responsibility and accountability for
their work. Rooney’s experience was not without its
challenges; however, she noted that implementing IBL
required time and diligent preparation. New models
like IBL require an investment in teacher education and
continued professional support.
Teaching Kids to Think Like Engineers
go.nmc.org/engi
(Breanna Draxler, Discover Magazine, December 2013.) A
new suite of open-ended standards has been developed
that seeks to give students experience with engineering
and technology by working together to solve problems.
> Leadership
How Computer Science Can Solve Problems in Biology
go.nmc.org/welsh
(Julia McWatt, Wales Online, 3 March 2014.) A
bioinformatics professor explains how learning
computer science enables children to make discoveries
in other scientific fields. Computer science is integral to
store and manage data, leverage data mining algorithms
to find informative patterns, and to produce statistics to
interpret results. > Practice
How Technology Has Changed Our Idea of
‘Knowledge,’and What This Means for Schools
go.nmc.org/knowle
(Dennis Pierce, eSchool News, 30 July 2013.) The concept
of knowledge has changed due to Internet innovations.
The author discusses how organically growing
online communities such as Reddit have proven that
knowledge is no longer fixed, but constantly evolving.
Students must now communicate and network as an
integral part of the learning process. > Practice
Systems Thinking
go.nmc.org/systems
(Centre for Ecoliteracy, 2013.) This essay emphasises
the need for children to consider themselves part of a
larger system and to think in terms of relationships,
connectedness, and context. > Practice
Itisnotenoughtobeableto
conceptualisedifficultchallenges
—onemustalsobeabletomake
thoseideaseasytograsp,easyto
share,andeasytosupport.
For Further Reading
who wish to learn more about complex thinking and
communication:
New National Curriculum to Teach Five Year Olds
Computer Programming
go.nmc.org/gove
(SteveMcCaskill,TechWeekEurope,8July2013.)England’s
Secretary of State for Education has overhauled the
curriculum to focus on teaching kids to create and
debug simple programs with the aim of encouraging
logical thinking, creativity, and interest in STEM. > Policy

Students as Co-Designers of Learning
Wicked Challenge:Those that are complex to even define, much less address
T
he notion that students could be designers and
architects of their learning environments is
inherently disruptive, even if the idea is to work
in collaboration with classmates and teachers
to co-construct learning. Nonetheless, there
is considerable evidence substantiating that when
students are given the tools and responsibility to
design their own learning environments, they become
more curious and more engaged. With the resources
available to the modern learner on the Internet, the
role of the teacher is shifting to being more of a mentor
and advisor in the learning journey. The challenge is
determining how the co-design process is developed.
Many are concerned that students — especially those
in primary school — do not have the insight necessary
to see the larger picture of their long-term learning,
which is a combination of personal goals and the
school and administration’s goals.
CCR Framework Element: Learning Practices
Overview
While the expert panel strongly supported the notion
of co-designed learning, there is little consensus
on what that actually means in broad practice. The
European Democratic Education Community states that
educational science data has proven the benefits of
the related concept of self-directed learning, citing an
increase in motivated, innovative, and lifelong learners.
Their mission is to promote “self-determined” learning
across European schools and universities in which
students choose how to spend their time in school
and pursue their curiosities. They believe integrating
more independent study, Internet research, games,
and project-based learning can engage students in
meaningful ways.129
Aspects of this challenge fall in the policy arena, others
in leadership, and some in the very definition of what
it means to be a teacher. Actually moving to a model
where a large number of schools routinely involve
students in the design of their own learning will be
complex. A concerted effort by political leaders, policy
makers, schools as well as labour, and local stakeholder
groups is needed to even begin to understand the scope
of this undertaking. Health studies, such as the one
conducted by JAMA Pediatrics, have cited how making
student-centred changes to the traditional school day
can impact student response and engagement. The
study suggests that beginning the school day later can
impact the sleep, mood, and behaviour of adolescents,
which ultimately relates to how students learn and how
well they perform in school.130
This finding offers some
basis for incorporating student needs in the learning
process.
There are few models that focus on how to include
students in the design of learning. Researchers in several
universities are exploring this challenge, but most of the
published work is still quite preliminary. Some of the
notable current work is that of individual teachers who
are informally documenting ideas and making the case
for greater use of multimedia, writing, and other sorts
of products that can become part of the curriculum,
assignments, and lectures. For example, Elizabeth
Allen, the Director of Online Communications at the
American School in London maintains a blog in which
one of the main categories is encouraging student-
generated content. She provides several examples of
how students can contribute useful materials to the
education ecosystem, including a book written by a
team of students on how to navigate career options
post graduation as well as student produced videos that
showcase their perspectives on pressing environmental
issues.131
While there needs to be an ongoing dialogue
among European education leaders to truly define what
is meant by student-designed learning, this kind of early
evidence indicates that students are more engaged
when they are involved in the development process.
Practice
Part of making sense of this challenge is understanding
the implications of a shift toward students being the
creators of resources that can become part of the
learning ecosystem. In this shift, there are inherent
opportunities for leaders and policy makers to help
define what constitutes quality student-produced
content, as the worry for many is that the quality of
content could suffer from too much learner input.
Currently much of this exploration is taking place in
research efforts within the tertiary education sector. The
Open University of Catalonia, for example published
an article in the European Journal of Open, Distance,

35Wicked Challenge
and E-Learning that explored quality aspects of student
content creation for use in online environments.132
They used three categories to organise the criteria —
content, format, and process — and each included focal
points. For example, the content category emphasises
the importance of consistency across language and
imagery, the format category encompasses creative and
accessible design, and the process category includes the
use of emerging technologies.
At the Hellerup School in Denmark, students share
responsibility with teachers for planning their work.
The school contains several different physical spaces
that enable children to engage with subject matter as
they choose, from private and quiet areas for deep and
critical thinking to playful areas that encourage them
to act out scenarios and do group work. Students there
are also constantly challenged to take responsibility for
their own learning progress; innovative timetables allow
them to start sorting through material together and
then work alone, according to their needs.133
While strategies like the one underway at Hellerup
show potential for primary and secondary schools, the
benefits and challenges of incorporating students in
the learning design process are still being examined
through research efforts at the tertiary education level.
For example, in the UK, Durham University’s Institute
of Physics is exploring the use of student-generated
content to enhance teaching practices.134
The goal of the
study is to identify ways to engage students more deeply
in the learning process by treating them as knowledge
creators. Approaching students as partners in learning
design is thought to make complex subjects more
approachable, and present a pathway to more student-
centred learning. Furthermore, the skills necessary to
develop high-quality content are those that have been
demonstrated to increase employability and success in
the workforce. In one of Durham University’s examples,
students helped develop interactive screen experiments
in physics courses. The study revealed that students’
knowledge acquisition was tremendously enriched
when they had more control over the design process,
and it is feasible that this approach could have similar
effects for primary and secondary students.
For Further Reading
who wish to learn more about students as co-designers
of learning:
When Kids Craft BYOD Policies
go.nmc.org/kidscraft
(John Spencer, Education Rethink, 5 March 2013.) A
teacher discusses how his sixth grade students created
their own BYOD policy. He found that his students had
very mature perspectives about mobile devices, equity,
and responsibility. > Policy
Students’Voices
go.nmc.org/voices
(Stephen Heppell, Heppell.net, accessed 31 January
2014.) At the annual BETT Show in 2014, students
from Norway, Sweden, and Denmark assembled in a
Scandinavian colloquium where they presented and
discussed a new learning evolution in which teachers
are now co-constructing learning with their students.
> Leadership
3 Reasons to Encourage Student-Generated Content
go.nmc.org/three
(Paul Moss, eLearning Industry, 30 October 2013.)
Student-generated content is an outcome of the organic
interaction and research that students participate in
daily online. The authors believe that teachers who
understand this concept can harness its power, teach
students to act responsibly with it, and help shape a new
learning culture. > Practice
Denmark to Open World’s First Lego School
go.nmc.org/lego
(Helen Russell, The Guardian, 22 April 2013.) The first
ever Lego school will be centred around inquiry-based
learning, a pedagogy that is planned to allow time for
creativity, play, and getting into a “state of flow” for
students. > Practice
The Future of Learning Environments
go.nmc.org/futurele
(Moa Dickmark, Core 77, 10 February 2014.) An architect
explains how workshops in which students explore and
question existing spaces at their school and homes can
better incorporate student feedback when designing
their learning spaces and schools. > Practice
Student Created Content Is an Exciting and Inspiring
Learning Tool that Teaches Many Skills
go.nmc.org/studen
(K. Walsh, Emerging Ed Tech, 19 November 2013.) When
students create content, they are developing literacy
skills, communication skills, presentation skills, and the
confidence to take control of their learning and harness
their creativity. > Practice

Important Developments in Educational Technology for
European Schools
E
ach of the six developments in educational
technology detailed in this section were selected
by the project’s expert panel, using the Horizon
Project’s Delphi-based process of iterative rounds
of study, discussion, and voting. In the NMC
Horizon Project, educational technology is defined
in a broad sense as tools and resources that are used
to improve teaching, learning, and creative inquiry.
While many of the technologies considered were not
developed for the sole purpose of education, they have
clear applications in the field.
The technologies, which the members of the expert
panelagreedareverylikelytodrivetechnologyplanning
and decision-making over the next five years, are
sorted into three time-related categories — near-term
technologies that are expected to achieve adoption in
one year or less; mid-term technologies that will take
two to three years; and far-term technologies, which
are forecasted to enter the mainstream of education
within four to five years. Each technology topic opens
with an overview of the topic and relates to areas of the
CCR Framework as pictured in the chart in the Executive
Summary.
The initial list of topics considered by the expert panel
was arranged into categories that were based on the
primary origin and use of the technology. The potential
applications of the technologies featured, specifically
in the context of European schools, were considered
in a series of online discussions that can be viewed at
europe.wiki.nmc.org/Horizon+Topics.
The expert panel was provided with an extensive set
of background materials when the project began
that identified and documented a range of existing
technologies used in both education and beyond.
The panel was also encouraged to consider emerging
technologies whose applications for schools may still
be distant. A key criterion for the inclusion of a new
technology in this edition was its potential relevance
to teaching, learning, and creative inquiry in European
schools.
In the first round of voting, the expert group reduced
the master list of topics to 12 technologies that were
researched in-depth by the NMC staff. Each was then
written up in the format of the Horizon Report and used
to inform the final round of voting.Technologies that do
not make the interim results or the final report are often
thoroughly discussed on the project wiki at europe.
wiki.nmc.org. Sometimes a candidate technology does
not get voted in because the expert panel believes it is
already in widespread use in schools, or, in other cases,
they believe the technology is more than five years
away from widespread adoption. Some technologies,
while intriguing, do not have enough credible project
examples to substantiate them.
There are currently seven categories of technologies,
tools, and strategies for their use that the NMC monitors
continuously. These are not a closed set, but rather are
intended to provide a way to illustrate and organise
emerging technologies into pathways of development
that are or may be relevant to learning and creative
inquiry. New technologies are added to this list in almost
every research cycle; others are merged or updated.
Collectively, the categories serve as lenses for thinking
about innovation; each is defined below.
> Consumer technologies are tools created for
recreational and professional purposes and were
not designed, at least initially, for educational use —
though they may serve well as learning aids and be
quite adaptable for use in schools.These technologies
find their ways into schools because people are using
them.
> Digital strategies are not so much technologies as
they are ways of using devices and software to enrich
teaching and learning, whether inside or outside of
the classroom. Effective digital strategies can be used
in both formal and informal learning; what makes
them interesting is that they transcend conventional
ideas and learning activities to create something that
is new, meaningful, and 21st century.
> Enabling technologies are those technologies that
have the potential to transform what we expect of our
devices and tools. The link to learning in this category
is less easy to make, but this group of technologies
is where substantive technological innovation begins
to be visible. Enabling technologies expand the reach
of our tools, make them more capable and useful, and
often easier to use as well.

37
> Internet technologies include techniques and
essential infrastructure that help to make the
technologies underlying how we interact with the
network more transparent, less obtrusive, and easier
to use.
> Learning technologies include both tools and
resources developed expressly for the education
sector, as well as pathways of development that
may include tools adapted from other purposes
that are matched with strategies to make them
useful for learning. These include technologies that
are changing the landscape of learning, whether
formal or informal, by making it more accessible and
personalised.
> Social media technologies could have been
subsumed under the consumer technology category,
but they have become so ever-present and so widely
used in every part of society that they have been
elevated to their own category. As well established
as social media are, they continue to evolve at a
rapid pace, with new ideas, tools, and developments
coming online constantly.
> Visualisation technologies run the gamut from
simple infographics to complex forms of visual data
analysis. What they have in common is that they tap
the brain’s inherent ability to rapidly process visual
information, identify patterns, and sense order in
complex situations.These technologies are a growing
cluster of tools and processes for mining large data
Important Developments in Educational Technology for European Schools
sets, exploring dynamic processes, and generally
making the complex simple.
The following pages provide a discussion of the six
technologies highlighted by the 2014 Horizon Project
Europe Expert Panel, who agree that they have the
potentialtofosterrealchangesineducation,particularly
in the development of progressive pedagogies and
learning strategies; the organisation of teachers’ work;
and the arrangement and delivery of content. As such,
each section includes an overview of the technology;
a discussion of its relevance to teaching, learning, or
creative inquiry; and curated project examples and
recommendations for further reading.
Consumer Technologies
> 3D Video
> Electronic Publishing
> Mobile Apps
> Quantified Self
> Tablet Computing
> Telepresence
> Wearable Technology
Digital Strategies
> Bring Your Own Device
(BYOD)
> Flipped Classroom
> Games and Gamification
> Location Intelligence
> Makerspaces
> Preservation/Conservation
Technologies
Internet Technologies
> Cloud Computing
> The Internet of Things
> Real-Time Translation
> Semantic Applications
> Single Sign-On
> Syndication Tools
Learning Technologies
> Badges/Microcredit
> Learning Analytics
> Massive Open Online
Courses
> Mobile Learning
> Online Learning
> Open Content
> Open Licencing
> Virtual and Remote Labo-
ratories
Social Media Technologies
> Collaborative Environ-
ments
> Collective Intelligence
> Crowdfunding
> Crowdsourcing
> Digital Identity
> Social Networks
> Tacit Intelligence
Visualisation Technologies
> 3D Printing/Rapid Proto-
typing
> Augmented Reality
> Information Visualisation
> Visual Data Analysis
> Volumetric and Holo-
graphic Displays
Enabling Technologies
> Affective Computing
> Cellular Networks
> Electrovibration
> Flexible Displays
> Geolocation
> Location-Based Services
> Machine Learning
> Mobile Broadband
> Natural User Interfaces
> Near Field Communication
> Next-Generation Batteries
> Open Hardware
> Speech-to-Speech Transla-
tion
> Statistical Machine Transla-
tion
> Virtual Assistants
> Wireless Power

Cloud Computing
Time-to-Adoption Horizon: OneYear or Less
C
loud computing refers to expandable, on-
demand services and tools that are served
to the user via the Internet from specialised
data centres, and consume almost no local
processing or storage resources. According to
the 2013 MATEL report, enabling technologies such as
cloud computing are among the key technologies for
primary and secondary education.135
Cloud computing
resources support collaboration, file storage,
virtualisation, and access to computing cycles, and
the number of available applications that rely on
cloud technologies have grown to the point that few
education institutions do not make some use of the
cloud, whether as a matter of policy or not. Over the
past few years, cloud computing has been established
as an efficient way for European businesses to protect
data,developapplications,deliversoftwareandonline
platforms, and to collaborate, and the Digital Agenda
for Europe is instrumental in supporting similar cloud-
based strategies in schools to boost collaboration,
productivity, and mobility in teaching and learning.
CCR Framework Element: Infrastructure
Overview
Clouds, especially those supported by dedicated data
centres, can be public, private, or a hybrid of these. Many
businesses use software as a service (SAAS), and API
services in the cloud to reduce IT overhead costs. Google
Apps, for example, has become a popular choice for
schools, and many have moved their email infrastructure
to Gmail and adopted Google Drive for document
sharing and collaboration. Whether learning takes place
at home, work, school, on the road, or in social spaces,
nearly every student who uses the network relies in
some fashion on cloud computing to access or share
their information and applications. Some are concerned,
however, that many public cloud services may not meet
national privacy and data protection standards and
requirements for schools and students. Private cloud
computing solves these issues by providing common
cloud solutions in secure environments, and hybrid
clouds provide the benefits of both types.
As part of the official Digital Agenda for Europe, the
European Commission is currently devising a cloud
computing strategy for better standards, safer contracts,
and more overall usage in both the private and public
sectors.136
There is a consensus that cloud-based services
provide a range of solutions related to infrastructure,
software, and security. By means of virtualisation, cloud
computing providers can deliver fully-enabled virtual
computing environments of almost any scale that can
be accessed from any connected device, seamlessly
and on demand. Cloud services have also proven to cut
the cost and time required for server maintenance, and
offer support for new tools that foster best computing
practices for easy sharing and mobility. They can negate
the need for specialised IT staff that can be expensive
and difficult to retain. Additionally, as the mobile
Internet has expanded, an increasing number of tablets
and other devices that are designed expressly to operate
in the cloud have entered the market. These devices
have price points that make them competitive for 1:1
computing and BYOD deployments, which refer to the
practice of students receiving their own school provided
tablet or computer, and bringing their own laptops,
tablets, smartphones, or other mobile devices with them
to class, respectively.
According to the Horizon Europe Panel, the rapid
integration of cloud computing into our everyday
routines — from technology infrastructure to
communication exchanges to the many apps and
resources used for informal learning — has accelerated
the interest of European schools in cloud computing. As
Cloudcomputinghasbecome
widelyrecognisedasameans
ofimprovingproductivity
andexpandingcollaboration
ineducation.
more individuals use cloud-based sharing services such
asDropboxandGoogleDriveintheirpersonallives,cloud
computing has become widely recognised as a means
of improving productivity and expanding collaboration
in education. In early 2014, Ministries of Education in

39Time-to-Adoption Horizon: One Year or Less
Finland and Estonia convened to plan a collaboration to
develop cloud services that will leverage digital learning
materials and applications to significantly boost the use
of the cloud in education in both countries.137
Relevance for Teaching, Learning, or
Creative Inquiry
A recent SafeGov.org and Ponemon Institute study of
UK schools revealed that the use of cloud services has
grown rapidly over the past five years, making digital
strategies such as BYOD, the flipped classroom, and
personalised and collaborative learning environments
fairly straightforward technologically.138
The Sotogrande
International School in Spain, for example, is using
Google Apps for Education to promote communication,
creativity, collaboration, and productivity among
teachers and students.139

King Solomon Academy is using Chromebooks,
inexpensive laptops that rely on ubiquitous connectivity
and cloud-based software and storage, for experiments
with blended learning in a seventh grade math
classroom.140
The teacher has implemented both a
flipped classroom model where the core content is
delivered via videos as homework, as well as a flex
model where the content is primarily delivered online.
Chromebooks enable these learning models because of
constant Internet connectivity to access different types
of educational resources.
While numerous cloud computing projects are currently
underway in Europe, including examples such as Project
Schools in the Cloud in Spain,141
Killingworth School in
the Cloud in the UK,142
and the Ballerup municipality
cloud project in Denmark,143
security and privacy
concerns have surfaced as key issues impeding more
widespread implementation. The SafeGov.org report,
Protecting Vulnerable Data Subjects, offers a list of
recommendations to European data protection officials,
schools and school authorities, parent associations, and
cloud providers for establishing codes of conduct. The
aim is for these policies to ensure safe and effective use
of cloud computing in European schools.144
Cloud Computing in Practice
Thefollowinglinksprovideexamplesofcloudcomputing
in use that have direct implications for European schools:
Galicia Use of the Open-Source Cloud
go.nmc.org/gali
Spain’s province of Galicia is piloting open-source
cloud solutions to provide students, teachers, and
administrators with cost-effective access to learning
materials while also encouraging collaboration between
teachers across Europe. > Policy
The School on the Cloud
go.nmc.org/eusoc
The School on the Cloud partnership is an ICT network
funded by the European Commission that works to
evaluate future resources and scenarios for education in
a cloud environment, then disseminate and expand best
practices. It currently includes 18 countries. > Leadership
Flat Connections
go.nmc.org/flat
Flat Connections is a series of independent collaborative
projects in which classrooms leverage cloud platforms
to connect with, mentor, and collaborate with other
classrooms across the globe. > Practice
For Further Reading
The following articles and resources are recommended
forthosewhowishtolearnmoreaboutcloudcomputing:
The Benefits of Cloud Computing in Education Are
Huge!
go.nmc.org/huge
(Gail Staines, Aspect Blogs, 27 June 2013.) Advantages
of using cloud services for schools include less in-house
maintenance such as storing and keeping up servers,
software, and external hard drives. > Leadership
What is the Future of Technology in Education?
go.nmc.org/whatis
(Matt Britland, The Guardian, 19 June 2013.) The author
argues that the future of technology in education relies
on access to learning resources and collaboration tools
by leveraging cloud platforms and services. Investments
in fast and robust Internet infrastructure are currently of
paramount importance to schools. > Leadership
Education in the Cloud
go.nmc.org/inth
(Przemyslaw Fuks, isgtw, 20 November 2013.) This
article describes how students can freely access lessons,
courses,andresearchregardlessofgeographicrestraints.
The cost of hardware necessary to create IT infrastructure
and software licences is no longer a barrier. > Practice

Tablet Computing
Time-to-Adoption Horizon: OneYear or Less
C
omputers as we know them are undergoing a
complete transformation. Laptops and desktop
computers are being replaced by devices that
offer the latest in natural user interfaces. For
children especially, touchscreens are quickly
becoming the most familiar way of interacting with
information. Indeed the Internet is full of videos of
toddlers effortlessly navigating their way around
on tablets, or even swiping the pages of print
publications, bewildered by their analogue nature.
Currently, the market for tablet computers is booming;
in 2014, tablets will make up fully half of the PCs sold
worldwide, according to the research firm Canalys.145
The category is led by the incredible success of the
iPad, which at the time of publication had sold more
than 170 million units, a number expected to rise
to over 366 million units by 2016, as predicted by
GigaOM.146
In the same timeframe, Samsung, Google,
and Amazon, as well as traditional PC vendors like
HP and Microsoft, are rapidly growing their share of
this market. Increased choice and competition will
continuetodrivedownretailprices.Tablets’consumer-
friendly reputations have led to their integration into
educational environments. Visually compelling and
highly portable, they are ideal tools for browsing
the Internet, viewing presentations and videos,
and accessing apps, giving school leaders reason to
position tablets at the centre of teaching and learning.
and Infrastructure
Overview
As 1:1 initiatives (programs where every student is
provided with a personal device to use throughout the
school day, and often at home) and BYOD initiatives
(where students bring their own devices) become more
commonplace in schools, leaders in the technology
industry have started designing and marketing tablets
specifically for educational purposes. This new angle
has led to developments in interface, feature sets, and
connectivity that are making tablets uniquely suited
for teaching and learning. Tablets have proven to be
an affordable 1:1 solution, but the affordances of these
mobile devices are not quite as complete in a school
setting. While it is quite easy to consume and interact
with information on a tablet, activities that engage
students in the co-creation and co-construction of
knowledge are limited by a design that discourages
typing.
With the advent of competition in this market, many
tablet manufacturers are hoping to help place large-
scale 1:1 initiatives in schools, and offer a range of
products and programmes to especially encourage the
educational use of tablets. Apple’s focus has been on
content production and dissemination with platforms
such as iTunesU, iBooks Textbooks, iBook Author, and
the Education Collections section in its app store.147
Samsung has stakes in the educational market as well;
the Samsung Smart Schools initiative employs Android-
basedinteractivewhiteboardsandsmartTVswithscreen
sharing capabilities to support collaborative learning in
the classroom. Now partnered with major educational
content publisher Houghton Mifflin Harcourt, Samsung
is working on software and educational materials to
create a tablet-computing ecosystem that consists of
hardware, software, and content. With successful pilots
already completed in South Korea, Australia, and the
United States, the Smart School solution is currently
underway in two schools in the UK.148
Oneofthemostusefulfeaturesoftabletsisthebreadthof
apps available for free or for small fees.With over 115,000
educational apps offered, iPad apps can be purchased
in bulk via the Volume Purchase Programme.149
Google
Play for Education is not far behind, with over 77,000
educational apps at the time of publication, in addition
to a growing list of hardware options that are designed
with education in mind.150
Samsung’s new Galaxy Tab,
released in April 2014, is the latest addition to the Google
Play for Education programme. The new educational
tablet features near field communication technologies
that are intended to give administrators an easy way to
coordinate an entire classroom of devices.
Creative Inquiry
Findings from the latest Survey of Schools: ICT in
Education report indicate a trend toward 1:1 initiatives in
European schools; at grade 8 (i.e. around 13.5 years old)
more students are in 1:1 classes than in other grades,
and most of these students are found in Spain, Norway

41
and Sweden.151
This trend demonstrates the growing
interest in understanding how tablets can support
learning inside and outside of school. A 2013 meta-study
on European educational pilots surveyed 31 recent
1:1 initiatives across 47,000 schools and 17,500,000
students in primary and/or secondary education across
19 European countries.152
The report found that national
and/orregionalauthoritiesareoftenthemaininitiatorsof
pilots, and are also often involved in the implementation
process. Supporting such experimentation in actual
educational settings provides guidance to students
and parents, logistical support, and teacher training,
especially at the school level.
Indeed, many schools leaders are intrigued by the
potential of tablets, but to realise this opportunity,
teachers must know how to use tablets in activity-based
and project-based learning, according to research on
1:1 initiatives mentioned above. Ongoing school-based
support and training is essential to helping practitioners
use tablets in the classroom; moreover, the study team
has recommended further investigation into the use
of hybrid learning models for teacher training; these
hybrid approaches leverage online components and
communities of practice reinforce the integration of
technology into instruction.
As tablets become more accessible and capable, an
increasing number of countries are identifying tablet
computing as a focal point of their national strategies for
education. Turkey’s FATIH project has plans to introduce
over ten million tablets into its public education system.
ItsgoalsaretoachieveICTubiquityinTurkishclassrooms,
and to reinforce formal and informal learning with
mobile technology.153
Similarly, Belgium has set forth a
plan to create a network of innovative schools to be test
beds for three novel, tech-based approaches to teaching
and learning; with ten schools in each test bed, the first
group will explore 1:1 computing and tablets.154
National
directives and policies are also encouraging schools in
France to experiment with tablets in the classroom;
Académie Nantes, for example, has integrated tablets
into its schools and reported their experiences on the
affordances of tablets for learning, providing detailed
notes on user production, ease of mobility, document
management solutions, and volume purchasing
programmes among other considerations.155
Tablet Computing in Practice
The following links provide examples of tablet
computing in use that have direct implications for
European schools:
The Creative Classrooms Lab
go.nmc.org/cclp
The “Creative Classrooms Lab” is a network of 30
Ministries of Education in Europe that is conducting
policy experimentations to collect evidence on
the implementation, impact, and up-scaling of 1:1
pedagogical approaches with tablets. > Policy
Boosting Learning through Tablets
go.nmc.org/boost
As part of a £3.5m strategy by the Education Endowment
Foundation, Rosendale Primary in South London is using
tablets to photograph and tag their work with notes
about how well they learned so they can analyse their
learning strategies. > Practice
French Students Ditch Books for Tablets (Video)
go.nmc.org/fran
Students in North Central France who are each given a
tablet at the age of seven appreciate the organisational
aspect of tracking their projects and studies without
needing multiple books and papers. > Practice
For Further Reading
for those who wish to learn more about tablet
computing:
Who Owns the Laptops and Tablets Used by
Students and Teachers, and How Does This Affect
Their Use?
go.nmc.org/own
(Michael Trucano, World Bank Blogs, 25 November 2013.)
This article discusses some of the different ownership
models in relation to a device’s usefulness being a
function of how people are permitted to use it. > Policy
iPad Research in Schools
go.nmc.org/hull
(University of Hull, accessed 28 March 2014.) Based
on eight schools in Scotland, this study discusses
management and leadership issues associated with
tablet deployment and how parental engagement with
learning is affected by personal devices. > Leadership
iPads Bring Students with Disabilities New Ways to
Participate, Excel in Education
go.nmc.org/concord
(Kathleen Ronayne, Concord Monitor, 14 August 2013.)
Using iPads, blind students can now translate written
words to audio with one touch; students with dyslexia or
other reading disorders can complete work using only
their voice; and students with autism can find alternative
ways to express their ideas. > Practice

Time-to-Adoption Horizon:Two toThreeYears
T
he culture around digital games is growing,
with the age of the average gamer increasing
every year. The gaming industry is producing a
steadystreamofgames thatcontinue toexpand
their nature and impact – they can be artistic,
social, and collaborative, with many allowing massive
numbersofpeoplefromallovertheworldtoparticipate
simultaneously. Now that tablets and smartphones
are commonplace, game play is a portable activity.
Once considered purely as entertainment, scientific
studies are revealing the impact games can have
on human behaviour, leading to their uptake in the
worlds of commerce, the military, and education,
amongotherareas.Similarly,therehasbeenincreased
attention surrounding gamification — the integration
of gaming elements, mechanics, and frameworks
into non-game situations and scenarios for training
and motivational purposes. Businesses especially
have embraced gamification as a way to design
programmes that incentivise productivity through
rewards, leader boards, and badges — elements that
are often integrated into mobile platforms. Although
still in its nascent stages in education, the gamification
of learning environments is gaining support among
educators who recognise that effectively designed
games can stimulate large gains in engagement,
productivity, creativity, and authentic learning.
Overview
Aligned with findings of the 2013 MATEL report, games
and gamification are positioned as key technologies
for primary and secondary education.156
The roots of
game-based learning can be traced back to 2003, when
a burgeoning body of research began exploring the
impact of game play on cognitive development. Since
then, games and simulations, digital and otherwise,
have been developed to help learners build social and
intellectual skills with greater goals in mind. A recent
report, The Potential of Digital Games for Empowerment
and Social Inclusion of Groups at Risk of Social and
Economic Exclusion, concluded that online and other
digital games can positively impact employment,
economic growth, and innovation by increasing socio-
economic inclusion of at-risk populations, including
youth who may be struggling academically. The report
also recommends that serious games and gamification
be integrated across industry, research, and learning
sectors.
Whenthegamingindustrybegantoincorporatenetwork
connectivity into game design, they revolutionised
game-play by creating vast virtual arenas where
participants from all over the world could connect,
interact, and compete. The Internet offers gamers
the opportunity to join massively multiplayer online
(MMO) role-playing environments and to build online
reputations based on their skills, accomplishments, and
abilities. In the last five years, games have converged
with natural user interfaces to create an experience for
players that more closely mimics real life, engaging users
with touch screens and gesture-sensing technologies.
Gamification applies gaming mechanics to routine
activities, often with the express purpose of engaging
and supporting people as they learn new skills. Simple.
com, for example, is a gamified banking service that
helps users master their finances. Similar game-
like environments can transform assignments into
exciting challenges, reward students for dedication
and efficiency, and offer a space for leaders to naturally
emerge. Badges are being increasingly used as a rewards
system for learners, allowing them, in many cases,
to publicly display their progress and skill mastery in
online profiles. In their report, Social Inclusion of Youth
with Mental Health Conditions, the United Nations also
suggests that games and gamification may enable
students with mental disabilities to better grasp learning
materials and exhibit improved behaviour.159
Creative Inquiry
Educational games promote social skills that youth need
to understand and confront complex social dilemmas
with diplomacy and mutual understanding. The EU-
funded SIREN project, for instance, aims to design
games to nurture children’s abilities to identify and
diffuse conflicts in a culturally sensitive manner, with
the overarching goal of creating a more harmonious
European society. In a case study published in 2013,
SIREN researchers tested the game on a group of 67
children, ages 9 to 12 years old.160
As the participants

43Time-to-Adoption Horizon: Two to Three Years
experimented with their resolution skills in simulated
scenarios, the study team found the approach effective
in helping students accurately perceive varying degrees
of conflicts.
Games that have gained mainstream popularity outside
of school are often viewed in a new light when they
are placed in an educational context. The best-selling
MMO game, Minecraft, is a good example: the premise
is equally appealing to children and adults, there are
no prescribed goals, and players are free to explore
a seemingly infinite virtual space and construct or
deconstruct their surroundings with blocks of various
materials.161
With thousands of children playing in their
free time, and learning math and design skills along
the way, school leaders are taking increasing note of
Minecraft’s potential for learning. BBC Radio 5 identified
at least 150 schools in the United Kingdom that already
use Minecraft to reinforce collaboration. The game was
highlighted as a potential gateway to computer science,
as players often are required to use programming skills
to overcome challenges within the virtual world.162
Researchers at the University of Warwick found that
gamified learning in online environments motivates
students to engage in higher order thinking. The
scientists established a framework to measure the
quality of a contribution in an online environment.
They observed that when students were obligated
to participate in the gamified discussion forum,
contributions increased, yet not a single person
achieved the highest level of thinking. On the other
hand, discussions that took place when students were
encouraged, rather than forced, to contribute in the
gamified platform were more productive, and resulted
in more learners reaching higher levels of thinking. The
study ultimately acknowledges that the success of a
gamified learning environment relies on achieving a
fair balance of external pressure and encouragement to
participate.163
Games and Gamification in Practice
The following links provide examples of games and
gamification in use that have direct implications for
European schools:
MAGICAL
go.nmc.org/magicaleu
This EU-funded project is exploring collaborative design
of educational games by primary and lower secondary
students. MAGICAL investigates the impact collaborative
design of educational games can have on learning, and
especially on support for key transversal skills, such as
strategic thinking and creativity. > Leadership
Minecraft at Viktor Rydberg School
go.nmc.org/minecr
At the Viktor Rydberg School in Sweden, secondary
students take a mandatory course on Minecraft in which
they learn about city planning and environmental issues
through gameplay. > Practice
The Research Game
go.nmc.org/eurg
This EU-funded Research Game project aims to inspire
and teach students the value and methodology of
scientific research. > Practice
For Further Reading
for those who wish to learn more about games and
gamification:
The Potential of Digital Games for Empowerment
and Social Inclusion of Groups at Risk of Social and
Economic Exclusion: Evidence and Opportunity for
Policy (PDF)
go.nmc.org/soci
(JRC-IPTS, September 2013.) This report includes
case studies that identify both the opportunities and
challenges in deploying digital games and gaming
in education, especially for those experiencing social
exclusion, by developing systems thinking, creativity,
and other 21st century skills. > Policy
Peace, Innovation, and Gamification: Can Games
Help Resolve Social Conflict?
go.nmc.org/peac
(Nilgun Arif and Alexis Franke, Voices from Eurasia,
27 August 2013.) The United Nations Development
Programme believes gaming can serve purposes such
as peace-building, disaster response, engagement of
youth with mental health disabilities, and farming and
economic development. > Leadership
Learning World: The Serious Side of Playing Games
(Video)
go.nmc.org/euronews
(Maha Barada, Euronews, 3 May 2013.) In a short
documentary, the potential for game and game design
to teach complex concepts is explained through
interviews with researchers and developers from MIT’s
Game Lab and The Consolarium in Scotland. > Practice

Mobile Learning
Time-to-Adoption Horizon:Two toThreeYears
U
NESCO describes mobile learning as “learning
that occurs in or outside of a classroom or
formal education setting, is not fixed to a
particular time or place, and is supported by
the use of a mobile device.”164
The latest crop
of mobile devices ranges from tablets to smartphones
to e-book readers, and other portable electronics. As
these devices grow more capable and user interfaces
more natural, combined with their constant Internet
connectivity, they are becoming increasingly useful
tools for learning. The unprecedented evolution of
thesedevicesandtheapplicationsthatrunonthemhas
illuminated their vast potential for educational use.
Learning institutions all over the world are not simply
adopting apps into their curricula, but developing
mobile strategies that consider the modification of
learningarrangementsinschools.Manyschoolsacross
Europe are taking advantage of these opportunities
in the form of 1:1 initiatives — programmes where
every student is provided with a personal device to use
throughout the school day, and often at home.
Overview
Mobile learning has profound implications for primary
and secondary education, where it is seen as facilitating
both non-formal and self-directed learning. The
portability of mobile devices, coupled with increasingly
fast cellular-based broadband connectivity, lead
naturally to envisioning the devices as a very enticing
learning tool. Ultimately, one of the biggest appeals
of mobile learning is that the devices themselves
naturally encourage exploration — a notion that is easily
demonstrated by placing a device in the hands of a small
child.Whetheritisconnectingwithnewpeopleviasocial
media or discovering local resources recommended by
an app, mobiles make it easy for people of all ages to
act upon their curiosities and expand their knowledge.
In many ways, mobile devices reflect a user’s personal
learning environment, encompassing their own
collection of apps and productivity features.
Additionally, the use of mobile devices can have a
transformative effect in the organisation of learning
within schools if students are allowed to use their own
devices in the classroom, personalise their use of ICT,
and granted more flexibility and choice. A 2013 report,
Overview and Analysis of 1:1 Learning Initiatives in Europe,
analysed a number of 1:1 initiatives and found that the
mobilelearningmovementhascreatedanewsetoftasks
for school leaders, including the provision of Internet
access; organising learning platforms and resources; and
training and supporting teachers.165
The report calls for
mobile learning and 1:1 initiatives that are underpinned
by evolved teaching approaches — the technology
must be supported by effective pedagogy, cultivated
through a flexible framework of clear objectives,
guidelines, and tools. According to the report, up-scaling
these programs will require evidence and widespread
sharing of best practices. Successful implementations
will involve a diverse network of stakeholders, including
teachers, administrators, parents, commercial suppliers,
and local sponsors.
Creative Inquiry
Because of their portability, flexibility, and continuously
improving interfaces, mobile devices are especially
enticing to schools, and in many regions of the world,
students are already accustomed to using mobile
devices in their daily lives. Research conducted in the
EU has shown that young people own and use mobiles
more than ever. In the 2013 Net Children Go Mobile study,
researchers surveyed youth ages nine to 16 across six
different countries in the EU — Denmark, Italy, Romania,
the UK, Ireland, and Portugal.166
The study revealed a
clear trend that young people are using mobile devices
to access the Internet in diverse environments. It is
becoming increasingly clear to schools that mobility is a
key feature of the digital age, and one that will shape the
future of education.
As mobile devices have become commonplace, a
number of European countries are looking for ways for
children to use their personal devices to access learning-
related content. Denmark’s national ICT strategy, for
example, allocates money specifically for developing
digital education resources and building streamlined
online and mobile platforms to distribute them. Their
goal is to achieve an “app store feel” for educational
content that allows teachers and students to download
material related to specific subject areas and learning
goals. By 2014, all students in Danish public schools

45Time-to-Adoption Horizon: Two to Three Years
are expected to have a mobile computing device and
access to wireless Internet. In order to meet this goal,
the majority of students are expected to bring their own
device, while schools will fill in the gaps for students
whose families lack the economic means to purchase
the devices on their own.167
While widespread use of mobile learning by most
schools is still two to three years away, there are
a number of EU Member States that are adopting
mobile-friendly policies and directives. For instance, the
Austrian Mobile Learning Companions project, which
encompasses 27 schools and 50 classrooms, encourages
schools to conduct classroom activities on tablets,
smartphones, and other portable devices.168
In Sweden,
Vittra Education has implemented a BYOD approach
across its 27 international private schools, in addition
to other measures to modernise education such as
creating personalised curricula for individual students
and eliminating classrooms.169
Innovative Pedagogy 1:1
go.nmc.org/slov
This national project in Slovenia provides students in
multiple schools with mobile devices to help them
integrate ICT into all subjects and allow their informal
learning habits to better mesh with the formal classroom
environment. > Policy
Mobile Learning in Fredrikstad
go.nmc.org/fredrikstad
The municipality of Fredrikstad in Norway launched
mobilelearningprojectsthatrangefromcross-continent
collaboration to paperless productivity to e-book pilots
at four primary and secondary schools. > Leadership
For Further Reading
for those who wish to learn more about mobile learning:
Policy Guidelines for Mobile Learning (PDF)
go.nmc.org/guidelines
(UNESCO, 2013.) This set of guidelines developed in
consultation with experts in over twenty countries seeks
to help policy-makers better understand what mobile
learning is and how it can expand education access in a
variety of settings. > Policy
Mobile Devices in Education: Part One
go.nmc.org/ptone
(Mark Pearce, Business Review Europe, 1 June 2013.) The
author analyses the BYOD trend, citing specific lessons
that education institutions can learn from businesses. He
believes allowing students to use their own devices in
class could give them a competitive edge. > Leadership
Turning on Mobile Learning in Europe (PDF)
go.nmc.org/nok
(Jan Hylén, UNESCO Working Paper Series on Mobile
Learning, 2012). This paper identifies strategies,
initiatives, and projects for mobile learning in formal
education across Europe. > Practice
Theuseofmobiledevices
canhaveatransformativeeffect
intheorganisationoflearning
withinschoolsifstudentsare
allowedtousetheirowndevices
intheclassroom,personalise
theiruseofICT,andgrantedmore
flexibilityandchoice.
Mobile Learning in Practice
The following links provide examples of mobile learning
in use that have direct implications for European schools:
6,000 High School Students in Catalonia Begin
Developing Apps in the Classroom
go.nmc.org/letsm
“Let’s Mobilise Computer Technology” is part of the
mSchools program backed by Mobile World Capital
Barcelona, the Regional Government of Catalonia,
the City of Barcelona, and GSMA Intelligence. It is an
initiative to encourage Catalonia’s high school students
to create and use mobile solutions in the classrooms,
and enhance their digital skills. > Policy

Personalised Learning
Time-to-Adoption Horizon: Four to FiveYears
P
ersonalised learning includes a wide variety of
approaches to support self-directed and group-
based learning that can be designed around
each learner’s goals. The idea includes concepts
like personalised learning environments and
networks, adaptive learning tools, and more. Using
a growing set of free and simple resources, such as a
collection of apps on a tablet, it is already quite easy to
supportone’songoingsocialandprofessionallearning
and other activities with a collection of resources and
tools that is always on hand. There are two paths of
development for personalised learning: the first is
organised by and for the learner, which includes apps,
social media, and related software. School goals and
interests are driving the other path, primarily in the
form of adaptive learning. In this pathway, which
envisions the development of tools and data streams
thatarestillsometimeawayfrombeingseeninschools,
adaptive learning is enabled by intervention-focused
machine intelligence that interprets data about how
a student is learning and responds by changing the
learning environment based on their needs. While the
concept of personalised learning is fairly fluid, it is
becoming more and more clear that it is individualised
by design, different from person to person, and built
around a vision of life-long learning.
Overview
The goal of personalised learning is to enable students
to determine the strategy and pace at which they learn
while allowing them to demonstrate their knowledge
acquisition in a manner that is uniquely their own.
Though effective personalised learning strategies focus
on the learner and not the technology, personalised
learningmaysignificantlydrawonenablingtechnologies
and tools. Free or nearly free cloud computing tools, for
example, allow users to easily store the content they
want, share their content with others, gather new and
relevant items, write personal commentary, complete
assignments, and more. YouTube, iTunes U, Facebook,
and other social media provide students with outlets
to discover new content, disseminate their own, and
develop digital portfolios they can carry with them and
build upon throughout their schooling.
The underlying technologies needed to support
personalised learning are relatively straightforward
and readily available now. For example, a person’s
smartphone or tablet and the collection of apps they
have chosen to download directly represents their
assortment of interests. With hundreds of thousands of
apps available in multiple marketplaces, it is easy to see
how no two people are likely to share the exact same set.
Everyone has distinctive preferences and approaches
learning and exploration differently — the basic premise
of personalised learning. The European Commission’s
“Opening Up Education” initiative, which explores this
premise as part of its mission, is working to strategise
best practices that incorporate the wide diversity of
options available to today’s students.170
Education researchers have emphasised the need
for learning settings to be adaptable and flexible in
order for personalised learning to take root. Students’
preferences and needs must be understood accurately
before designing or implementing personalised
learning scenarios and activities. The goal is to give the
student the flexibility to make their learning as effective
and efficient as possible, but adequate mentorship,
especially at the primary and secondary school level, is
still a clear necessity. In this model, there is a need for
teachers to adjust their roles in the classroom to focus
less on dispensing information through lectures and
more on being guides
Creative Inquiry
Personalised learning is, at its core, a way to allow
students to approach learning in ways best suited to
their individual needs. Some students, for example,
may benefit from the practice of keeping track of, and
curating, their own resource collections. The EU-funded
Responsive Open Learning Environments (ROLE) project
took this approach in an effort to study the impact
of student-created environments for personalised
learning.171
Resources likeYouTube, Wikipedia, and Flickr
were used to support teachers in developing personal
learning environments for their students. Over the
four years of the project, ROLE developed, tested, and
deployed an operating learning environment and a
collection of ROLE-designed widgets. However, despite
the fact that there is a growing range of easy-to-use

47Time-to-Adoption Horizon: Four to Five Years
tools that could be used to construct personal learning
resources, the emerging focus on helping students
assess and select tools is still somewhat nascent,
justifying the placement of personalised learning on the
far-term horizon.
Adaptive learning software in the form of online learning
platforms is an emerging area within the personalised
learning space, but one that shows the potential
of guiding students’ individual progress through a
set of material via an analysis of their responses to
mini-quizzes or prompts in real time. These tools are
envisioned as providing students and educators with
highly personalised information about how lessons
are progressing, with adjustments made on the fly
as needed. “Realize It” is an online learning platform
developed in Ireland that uses such data to react and
adapt to a student’s behaviour and performance.172
The software indicates the learner’s progress in relation
to learning objectives, outlines his or her state of
knowledge at a granular level, and uses the gathered
evidence to determine the most appropriate next step
for the student.
This type of personalisation is seen as central in the
evolution of learning, and while scalable methods
and concepts will take some time to refine, there
is considerable consensus among government,
policymakers, and school leaders of the importance
of this work. A partnership between eight European
countries is currently developing an adaptive learning
program called TERENCE, targeted to children age
7-11 who have demonstrated difficulty with text
comprehension.173
TERENCE aims to stimulate high-
level cognitive text processing through tailored “smart
games” that are designed to foster story-reasoning
skills. Ultimately, teachers will be able to customise the
types of stories and games for each student. TERENCE
is envisioned as a cross-disciplinary effort, with future
plans to build adaptive learning models for art and
design, computers, engineering, and linguistics.
Personalised Learning in Practice
The following links provide examples of personalised
learninginusethathavedirectimplicationsforEuropean
schools:
WeSPOT
go.nmc.org/wespot
weSPOT is a research initiative that aims to strengthen
scientific inquiry in classrooms and curricula in the EU by
leveraging students’ personal curiosity and experience
to deepen their conceptual knowledge. > Leadership
Colegio Montserrat’s Personalised Learning
go.nmc.org/cole
At Colegio Montserrat in Barcelona, Spain, every fourth-
year student receives their own iPad or laptop, which
they use with the school’s Moodle learning management
system. This allows them to choose their own pathways
through a learning landscape while their progress is
charted in their personal e-portfolios. > Practice
Collaboration and Personalisation in Riihimäki,
Finland (PDF)
go.nmc.org/collabo
At Peltosaari School, a learning approach called
“progressive inquiry” is used to personalise learning.
Primary school students tackle challenging topics and
present their own ideas and solutions in group settings.
> Practice
For Further Reading
for those who wish to learn more about personalised
learning:
Future Learning Environments (Video)
go.nmc.org/wheeler
(Steve Wheeler, Learning Technologies, 29 January 2013.)
A media specialist and educator from the UK explores
ways in which emerging technologies can be used in a
more participatory, personalised model for education.
> Leadership
One Essential Resolution for Educators in 2013 —
A Personal Learning Environment
go.nmc.org/insights
(Debbie Morrison, Online Learning Insights, 1 January
2013.) This perspective on PLEs includes formal
and informal learning experiences and a variety of
educational resources. > Practice
What Personalised Learning Really Means for
Modern Teachers
go.nmc.org/means
(Jennifer Kelly, Edudemic, 4 August 2013.) Personalised
learning is not about the technology, but technology
does help scale the method by empowering a teacher
to keep a larger number of students at different levels
moving forward simultaneously. > Practice

Virtual and Remote Laboratories
Time-to-Adoption Horizon: Four to FiveYears
V
irtual and remote laboratories reflect a
movementamongmanyeducationinstitutions
to make the equipment and elements of
a working science laboratory more easily
available to learners, via special software
running on the Internet. Virtual laboratories are
web applications that emulate the operation of
physical laboratories and enable students to practice
techniques or run common experiments in a “safe”
environment either before using real instruments and
equipment, or in place of them. Students can typically
access virtual labs 24/7, from wherever they are,
and run the same experiments over and over again,
varying an array of factors and input values. Remote
laboratories, on the other hand, provide a virtual
interface to a real, physical laboratory. Institutions
that do not have access to high-calibre lab equipment
can run experiments and perform lab work online,
accessing the tools from a central location. Users
are able to manipulate the equipment and watch
the activities unfold via a webcam on a computer or
mobile device. This provides students with a realistic
view of system behaviour and allows them access to
professional laboratory tools from anywhere.
CCR Framework Element: Infrastructure
and Connectedness
Overview
Virtual and remote laboratories are not new
technologies, though they have become the subject
of many important discussions about improving
STEM education — especially in schools that cannot
afford expensive technology and equipment. The EU-
funded project “UniSchooLabs” is one such project that
addresses this gap of access.174
By collaborating with
several universities, primary and secondary schools
across the continent can use high-quality tools through
computers and other devices.“UniSchooLabs”leverages
both virtual and remote labs, which, while often spoken
of together, are different in significant ways.
Remote laboratories enable users to conduct
experiments and participate in activities via the Internet
usingremotelycontrolledbutreallaboratoryequipment.
Virtual laboratories are interactive online environments
for performing experiments with simulated equipment.
Both, however, offer the promise of authentic laboratory
experiences regardless of the locale of the user. In both
cases, students are still accountable for data collection
and analysis, though some virtual labs have built-in
tools to aid the lab write-up process. Likewise, both
approaches are designed to mimic the same interactions
users experience in a traditional “hands-on” laboratory,
where users manipulate materials, measure liquids, and
press buttons. Online users are able to control these
actions through an interface. The online environment
allows users to see the consequences of their actions
as they unfold, whether simulated in virtual labs or with
real equipment in remote labs. If the user does not get
the results they desire, there is flexibility to re-do the
experiment.
There are several notable hybrid virtual/remote
laboratories, including the HYPATIA project, which
enables college students to work with their teachers
to study the fundamental particles of matter and their
interactions through the inspection of the graphic
visualisation of the products of particle collisions. The
work done by students and teachers through HYPATIA
directly informs the ATLAS experiment at the world’s
most powerful particle accelerator, the LHC in the
European Particle Research Centre (CERN) in Geneva.175
Creative Inquiry
Virtual and remote laboratories are responses to an
increasing emphasis in schools on creating more
authentic learning experiences in online education.
Though the technology is still at least four to five years
away from mainstream use in European schools, its
pedagogical benefits are clear. Virtual and remote labs
offer flexibility, as students can run experiments both in
and outside of school. Because these labs are designed
to allow easy repetition of experiments, there is less
pressure on students to execute perfectly the first time.
After learning what did not work, they can easily make
adjustments to their processes and get different results.
In the controlled environments of virtual and remote
laboratories, students’ safety can be ensured, even if
they make an error. In school settings, this solves a
number of issues involved with having children exposed
to potentially dangerous materials and processes. It

49Time-to-Adoption Horizon: Four to Five Years
is especially true in scenarios involving chemicals or
radioactive experiments. Teachers hesitant to engage
in certain types of inquiry can now engage students
in significant laboratory work easily, at low cost, and
from anywhere. Most remote and virtual labs are
currently either the result of high profile, well-funded
university-level collaborations or targeted government
grants. The “UniSchoolLabs” project, mentioned earlier,
is creating an infrastructure to enable primary and
secondary schools to remotely access university science
laboratories through Internet-based services and mobile
learning devices. Educators have access to a catalogue
of available online laboratories, an archive of activities
created by other users, and a tool for creating new
activities or reusing existing ones.
For students, one of the most compelling features
of these online labs is that they can deliver realistic
scientific experiences that a student may not find even in
the physical labs at their schools. This is one of the goals
of the “Go Lab” project, an EU initiative that provides a
diverse set of online labs for learners.176
Through the
virtual “International Space Station (ISS) 3D Teaching
Tool,” for example, students role-play as astronauts,
navigating a 3D replica of the ISS as it orbits earth.177
Similarly, the “Discovery Space Portal” gives them
remote access to six robotic telescopes so they can track
real astronomy and astrophysics data.178
Labster
go.nmc.org/labst
Labster, a Denmark company, created a virtual lab where
an interactive molecular 3D animation makes molecular
processes visible that would normally be obscured
behind the walls of physical machinery. > Practice
Real Science in Sweden
go.nmc.org/mar
In the Swedish town of Lysekil, secondary students
used virtual tools to explore the marine environment of
the Gullmar Fjord on the Swedish west coast, learning
in the process how scientific knowledge is created.
The students accessed a virtual ocean acidification
laboratory to conduct studies on acidification of the
marine environment. > Practice
Virtual Physics Lab
go.nmc.org/virphy
Kosovo schools are using an online virtual physics lab
that simulates 30 experiments in which students can
manipulate variables and observe outcomes. > Practice
For Further Reading
for those who wish to learn more about virtual and
remote laboratories:
UniSchooLabs Toolkit: Tools and Methodologies to
Support the Adoption of Universities’Remote and
Virtual Labs in Schools (PDF)
go.nmc.org/unischool
(A. Ceregini et al., Consiglio Nazionale delle Ricerche
and Istituto per le Tecnologie Didattiche, July 2012.)
This paper describes a project funded by the European
Commission that aims to improve science education
across the continent by promoting collaboration
between universities and schools. > Leadership
Education Online: The Virtual Lab
go.nmc.org/eduon
(M. Mitchell Waldrop, Nature.com, 17 July 2013.) This
article explores online environments that enable
students to access real data from remotely controlled
instruments, allow them to upload and organise their
personal findings and data, and simulate laboratory
experiences. > Practice
Flipping Lab Science with Remote Labs
go.nmc.org/fliplab
(Jim Vanides, HP Blog Hub, 18 June 2012.) The author
explores the role of remote science labs in the flipped
classroom model. Students have more time to explore
the material and run more iterations of an experiment.
> Practice
Virtualandremotelaboratories
areresponsestoanincreasing
emphasisinschoolsoncreating
moreauthenticlearning
experiencesinonlineeducation.
VirtualandRemoteLaboratoriesinPractice
The following links provide examples of virtual and
remote laboratories in use that have direct implications
for European schools:
LiLa
go.nmc.org/lila
The EU-funded Library of Labs project (LiLa) was an
initiative of eight universities and three companies to
exchange and provide access to remote experiments.
It included a scheduling system, connection to library
resources, a tutoring system, and a 3D environment for
online collaboration. > Leadership

Horizon Report Europe. 2014 Schools Edition

51
The 2014 Horizon Project Europe Expert Panel
Stefania Aceto
MENON Network
International Organisation
Helga Bechmann
Multimedia Kontor Hamburg
GmbH
Germany
Jean-Pierre Berthet
École Centrale de Lyon
France
Roger Blamire
European Schoolnet
Stefania Bocconi
Institute for Educational
Technology of the National
Research Council of Italy (ITD-CNR)
Italy
Charlotte Bosworth
OCR
United Kingdom
Jeroen Bottema
Inholland University of Applied
Sciences
The Netherlands
Deirdre Butler
St. Patrick’s College, Dublin
Ireland
Nuria De Salvador
Teacher/Researcher
Spain
Simon Drazic
Secondary School Teacher
Slovenia
Lucian Cornel Duma
Special School Caransebes
Romania
Jelmer Evers
UniC, Utrecht
The Netherlands
Elizabeth FitzGerald
Open University
United Kingdom
Mario Franco
Millennium.edu
Portugal
Claus Gregersen
Herning Gymnasium
Denmark
Larry Johnson
Co-Principal Investigator
Management/Editorial Board
New Media Consortium
Guus Wijngaards
Co-Principal Investigator
Inholland University of
Applied Sciences
The Netherlands
Samantha Adams Becker
Horizon Project Director
Lead Writer
Marta Caceres Piñuel
Editorial Board
CSEV
Spain
Jim Devine
Research Team/ Editorial Board
DEVINE Policy | Projects | Innovation
Ireland
Gavin Dykes
Cellcove Ltd
United Kingdom
Øystein Johannessen
Management/Research Team/
Editorial Board
Qin AS
Norway
Panagiotis Kampylis
JRC-IPTS
Holly Ludgate
Editorial Board
Yves Punie
JRC-IPTS
Riina Vuorikari
JRC-IPTS
Michele Cummins
Research Manager
Dawn Hallybone
Oakdale Junior School
United Kingdom
Paul Hine
Hine Consultancy
United Kingdom
Anna Hoberg
Fraunhofer Institut IAO Fraunhofer
Gesellschaft
Germany
Jan Hylén
Ivar H Konsult
Sweden
Neil Ingram
Bristol University
United Kingdom
Ivailo Ivanov
Lauder Jewish Elementary &
High School
Bulgaria
William Jenkins
Tech Stories
United Kingdom
Kiira Kärkkäinen
FCG International Ltd
Finland
Vibeke Kløvstad
Norwegian Centre for ICT in
Education
Norway
Ioanna Komninou
First Experimental Upper High
School of Athens
Greece
Harald Kraemer
Zürcher Hochschule der Künste
Switzerland
Anne Looney
National Council for Curriculum
and Assessment
Ireland
Ann Michaelsen
Sandvika Upper Secondary School
Norway
Tao Papaioannou
University of Nicosia
Cyprus
Serge Ravet
Learning Agency Network
France
Stasele Riskiene
Kursenu Pavenciu Mokykla
Lithuania
Steven Ronsijn
Sint-Lievenscollege Gent
Belgium
Gabriel Rubio Navarro
Ministry of Education
Spain
Tiina Sarisalmi
City of Orivesi
Finland
Ursula Simmetsberger
Education Group
Austria
Magdalena Sverc
Martin Slomsek Institute,
Innovative Classrooms Project
Slovenia
Pieter Swager
Inholland University of Applied
Sciences
The Netherlands
Marta Turcsanyi-Szabo
Etvos University
Hungary
Michael van Wetering
Kennisnet
The Netherlands
Stephan Vincent-Lancrin
OECD
Steven Edwin Vosloo
UNESCO
Barbara Wasson
University of Bergen
Norway

Endnotes and Links
1 http://is.jrc.ec.europa.eu/pages/EAP/SCALECCR.html
2 http://ftp.jrc.es/EURdoc/JRC83167.pdf (PDF)
3 http://www.eun.org
4 Mainstream use is defined for the purpose of the project as when about 20%
of institutions adopt the technology within the period discussed. This figure,
based on the research of Geoffrey A. Moore, refers to the critical mass of
adoptions needed for a technology to have a chance of entering broad use.
6 http://www.lse.ac.uk/media@lse/research/EUKidsOnline/Home.aspx
7 http://www.klascement.net
8 http://umatzat.net/umatzat-Computers-and-Education-pre-print-14-07-2012.
pdf (PDF)
9 http://taccle2.eu/
10 http://bscl.fit.fraunhofer.de/en/usage_maptool.html
11 http://www.itslearning.eu/
12 http://thenextweb.com/facebook/2013/10/30/facebook-passes-1-19-billion-
monthly-active-users-874-million-mobile-users-728-million-daily-users
13 http://www.ebizmba.com/articles/social-networking-websites
14 http://www.emarketer.com/Article/Social-Networking-Reaches-Nearly-One-
Four-Around-World/1009976
15 http://wearesocial.net/blog/2014/02/social-digital-mobile-europe-2014/
16 http://mashable.com/2013/08/18/social-media-teachers
17 http://www.internetworldstats.com/facebook.htm
18 http://www.ons.gov.uk/ons/rel/rdit2/internet-access---households-and-
individuals/social-networking--the-uk-as-a-leader-in-europe/sty-social-
networking-2012.html
19 http://www.theatlantic.com/technology/archive/2013/04/why-do-people-
use-facebook/274721
20 http://www.straitstimes.com/the-big-story/case-you-missed-it/story/
whatsapp-mum-way-too-much-20140129
21 http://www.bettshow.com/seminar/Connected-Learners-Creating-a-global-
classroom
22 http://www.linkedin.com/groups/Prime-Teachers-Network-4127067
23 http://www.linkedin.com/groups/Teaching-English-in-Europe-TEFL-4147343
24 http://www.kennisnet.nl/themas/sociale-media/
25 http://www.lse.ac.uk/media%40lse/research/EUKidsOnline/EU%20Kids%20
II%20(2009-11)/EUKidsOnlineIIReports/Final%20report.pdf (PDF)
26 http://eur-lex.europa.eu/legal-content/EN/TXT/?uri=celex:52013SC0341
27 http://e-safety4etwinners.wikispaces.com/
28 http://www.learn2teach.eu/
29 http://www.etwinning.net/
30 http://ec.europa.eu/enterprise/policies/sme/promoting-entrepreneurship/
education-training-entrepreneurship/index_en.htm
31 http://ec.europa.eu/enterprise/policies/sme/promoting-entrepreneurship/
files/education/entredu-manual-fv_en.pdf (PDF)
32 http://eacea.ec.europa.eu/education/eurydice/documents/key_data_
series/151EN.pdf (PDF)
33 http://ec.europa.eu/education/policy/strategic-framework/index_en.htm
34 http://eur-lex.europa.eu/LexUriServ/LexUriServ.
do?uri=SWD:2012:0374:FIN:EN:PDF (PDF)
35 http://creative.eun.org/c/document_library/get_file?uuid=de69cfbe-32c9-
40ab-ba05-f6a4e92c3151&groupId=96459
36 http://www.itslearning.eu/flipping-the-classroom-at-sandgotna-school
37 http://www.hugs.no/om-skolen/flipped-classroom
38 http://www.euronews.com/2012/11/16/flipped-classrooms-improve-learning/
39 http://www.unesco.org/new/fileadmin/MULTIMEDIA/HQ/CI/CI/pdf/Events/
English_Paris_OER_Declaration.pdf (PDF)
40 http://ec.europa.eu/education/policy/strategic-framework/education-
technology.htm
41 http://www.openeducationeuropa.eu/en
42 http://openeducationalresources.pbworks.com/w/page/24838043/
Approaches and models
43 http://www.poerup.info/
44 http://oerpolicy.eu/
45 http://www.bookinprogress.it/mission.php
46 http://www.oercommons.org/
47 http://www.iskme.org/our-ideas/iskmes-teachers-makers-academy
48 http://www.iskme.org/our-work/oer-fellowship-program
49 Blended learning is often used as a synonym for hybrid learning, although
several authors would distinguish between the two. For our purposes, we are
using the term hybrid learning to encompass both perspectives.
50 http://files.eric.ed.gov/fulltext/ED537334.pdf (PDF)
51 http://blog.wowzers.com/bid/311585/Dutch-Schools-Make-News-with-iPad-
only-Instruction-Methods
52 http://ec.europa.eu/digital-agenda/futurium/sites/futurium/files/interviews/
GDudeney_NHockly_Synthesis.pdf (PDF)
53 http://creative.eun.org/c/document_library/get_file?uuid=de69cfbe-32c9-
40ab-ba05-f6a4e92c3151&groupId=96459
54 http://fcl.eun.org/c/document_library/get_file?uuid=ee8ceb88-48b8-4435-
808e-9bb25ff01322&groupId=10163
55 http://umatzat.net/umatzat-Computers-and-Education-pre-print-14-07-2012.
pdf (PDF)
57 https://www.youtube.com/watch?v=3aSgLYgLnSY (Video)
58 http://european-agency.org/sites/default/files/Belgium-Flemish-_exa-bednet.
pdf (PDF)
59 http://www.wereldschool.nl/
60 http://www.virtualschoolsandcolleges.info/
61 http://www.virtualschoolsandcolleges.info/case-studies
62 http://www.inclusiontrust.org.uk/notschool/
63 http://formacionprofesorado.educacion.es/
64 http://www.europeanschoolnetacademy.eu/
65 http://geografija6-8.mkp.emokykla.lt/lt/sisteminiai/meniu/teisinis/apie-
projekta/
66 http://taccle2.eu/
67 http://www.eurodl.org/?article=283
68 http://static.samlearning.com/site/uploads_samlearning.com/2012/09/
Impact-layout-V10_T_Cal.pdf (PDF)
69 http://www.samlearning.com/
70 http://go.nmc.org/lace
71 http://ec.europa.eu/programmes/erasmus-plus/index_en.htm
72 http://ec.europa.eu/programmes/horizon2020
73 http://ec.europa.eu/esf/home.jsp?langId=en
74 http://www.oecd.org/education/school/synergies-for-better-learning.htm
75 http://www.itslearning.eu/
76 http://www.itslearning.eu/flint-high-school-uk
78 http://ipts.jrc.ec.europa.eu/publications/pub.cfm?id=6359
79 http://www.nrpslo.org/en/noq/partners/centre_of_the_republic_of_slovenia_
for_vocational_education_and_training.aspx
80 http://itec.eun.org/
81 http://keyconet.eun.org/c/document_library/get_file?uuid=947fdee6-6508-
48dc-8056-8cea02223d1e&groupId=11028
82 http://ec.europa.eu/digital-agenda/en/news/survey-schools-ict-education
83 Ibid.
84 http://essie.eun.org
85 http://www.oecd.org/education/school/TiF (2013)--N°4 (eng)--v2.pdf (PDF)
86 http://www.icicte.org/Proceedings2013/Papers 2013/05-1-Krumsvik.pdf (PDF)

53
87 http://www.ijhssnet.com/journals/Vol_3_No_17_September_2013/2.pdf
88 http://edukata.fi/
89 http://www.europeanschoolnetacademy.eu/
90 http://www.lse.ac.uk/media@lse/research/EUKidsOnline/EU%20Kids%20I%20
(2006-9)/EU%20Kids%20Online%20I%20Reports/EUKidsOnlineFinalReport.
pdf (PDF)
do?uri=OJ:L:2006:394:0010:0018:en:PDF (PDF)
92 http://www.lse.ac.uk/media@lse/research/EUKidsOnline/Home.aspx
95 http://ec.europa.eu/programmes/erasmus-plus/index_en.htm
96 http://ec.europa.eu/programmes/horizon2020
97 http://ec.europa.eu/esf/home.jsp?langId=en
98 http://itec.eun.org
99 http://www.ortamerica.org/site/News2?page=NewsArticle&id=10247&news_
iv_ctrl=0&abbr=news_
100 http://net.educause.edu/ir/library/pdf/eli3009.pdf (PDF)
101 https://www.zooniverse.org
102 http://watch.birds.cornell.edu/CamClickr
103 http://www.evolutionmegalab.org
104 http://veinternational.org
105 http://ec.europa.eu/education/policy/vocational-policy/doc/alliance/work-
based-learning-in-europe_en.pdf (PDF)
106 http://www.establish-fp7.eu
107 http://www.cardet.org/authentic/index.php/en
108 http://www.museofabber.com/
109 http://www.makerfairerome.eu/en
110 http://made-bcn.org
111 http://www.eucen.eu/sites/default/files/OECD_RNFIFL2010_Werquin.pdf(PDF)
112 http://epp.eurostat.ec.europa.eu/statistics_explained/index.php/
Unemployment_statistics
113 http://sciencecamps.eu/
114 http://www.sciencemuseum.org.uk/visitmuseum/Plan_your_visit/events/
festivals/robot_safari.aspx
do?uri=OJ:C:2012:398:0001:0005:EN:PDF (PDF)
116 http://www.cedefop.europa.eu/en/about-cedefop/projects/validation-of-non-
formal-and-informal-learning/european-inventory.aspx
117 http://www.lemproject.eu/the-project
118 https://www.youthpass.eu/en/youthpass/
119 http://www.iste.org/docs/ct-documents/computational-thinking-operational-
definition-flyer.pdf?sfvrsn=2
120 http://www.slideshare.net/jurgenappelo/complexity-thinking?ref=http://
less2011.leanssc.org/program/complexity-and-systems-thinking/
121 http://watersfoundation.org/systems-thinking/definitions
122 http://www.iste.org/docs/ct-documents/computational-thinking-operational-
definition-flyer.pdf?sfvrsn=2
123 http://ec.europa.eu/enterprise/policies/innovation/policy/business-
innovation-observatory/files/case-studies/08-bid-analytics-decision-making_
en.pdf (PDF)
124 http://www.sas.com/offices/europe/uk/downloads/bigdata/eskills/eskills.pdf
(PDF)
125 http://eacea.ec.europa.eu/education/eurydice/documents/thematic_
reports/133en.pdf (PDF)
126 http://www.nytimes.com/2014/03/24/world/europe/adding-coding-to-the-
curriculum.html?_r=1
127 http://www.pss-comenius.eu
128 http://ejolts.net/files/journal/5/2/Rooney5%282%29.pdf (PDF)
129 http://www.eudec.org/Democratic+Education
130 http://archpedi.jamanetwork.com/article.aspx?articleid=383436
131 http://adaptivateblog.com/
132 http://www.eurodl.org/?article=459
134 http://www.iop.org/activity/groups/subject/hed/calendar/info/file_54869.pdf
(PDF)
136 http://ec.europa.eu/digital-agenda/
137 http://www.minedu.fi/OPM/Tiedotteet/2014/01/koulutuspilvi_mom.
html?lang=en
138 http://safegov.org/2013/5/23/safegovorg-and-ponemon-institute-uk-schools-
study-released
139 http://www.sis.ac/page.cfm?p=558
140 http://www.ictineducation.org/home-page/2014/1/31/review-of-the-google-
chromebook.html
141 http://joinup.ec.europa.eu/community/osor/news/spains-galicia-research-
open-source-cloud-use-schools
142 http://blog.ted.com/2013/12/16/the-first-school-in-the-cloud-opens/
143 https://joinup.ec.europa.eu/community/osor/news/danish-school-switch-
open-source-based-cloud-pcs
144 http://www.safegov.org/media/53807/safegov.org_report_on_protection_
vulnerable_data_subjects.pdf (PDF)
145 http://www.canalys.com/newsroom/tablets-make-50-pc-market-2014
146 http://research.gigaom.com/report/forecasting-the-tablet-market-over-366-
million-units-by-2016
147 https://www.apple.com/education/ipad/apps-books-and-more
148 http://www.zdnet.com/samsung-launches-its-smart-school-system-in-the-
uk-7000010792/
149 http://www.apple.com/education/it/vpp
150 http://www.appbrain.com/stats/
151 http://essie.eun.org/
153 http://erg.sabanciuniv.edu/sites/erg.sabanciuniv.edu/files/Fatih.summary.pdf
(PDF)
154 http://www.eun.org/c/document_library/get_file?uuid=ff2e0e00-172f-4f52-
b611-1d7ab271be8b&groupId=43887
155 http://www.pedagogie.ac-nantes.fr/1369731934531/0/fiche___
article/&RH=1176968804625
159 http://www.un.org/esa/socdev/documents/youth/youth-mental-health.pdf
(PDF)
160 http://sirenproject.eu/bib/towards-validating-game-scenarios-teaching-
conflict-resolution
161 http://www.bbc.co.uk/programmes/p01s0tkm
162 http://www.bbc.com/news/magazine-23572742
163 http://www.cedma-europe.org/newsletter%20articles/Inside%20Learning%20
Technologies%20and%20Skills/Is%20Gamification%20Good%20for%20
Learning%20%28Apr%2013%29.pdf (PDF)
164 http://unesdoc.unesco.org/images/0021/002161/216165e.pdf (PDF)
166 http://www.netchildrengomobile.eu/wp-content/plugins/downloads-
manager/upload/1stShortReport_web-colori_ultimo.pdf (PDF)
167 http://unesdoc.unesco.org/images/0021/002161/216165e.pdf (PDF)
168 http://www.eun.org/c/document_library/get_file?uuid=4a576578-e619-4689-
84f2-baa468d07396&groupId=43887
169 http://openeducationeuropa.eu/en/blogs/vittra-schools-sweden-use-
personal-devices-and-redesigned-learning-spaces-modernise-education
171 http://www.role-project.eu/
172 http://realizeitlearning.com/innovation/adaptive-learning/
173 http://www.terenceproject.eu/web/
guest;jsessionid=283F2744B1810A35CAA1E5D92BE27FC2
174 http://unischoolabs.eun.org/
175 http://hypatia.phys.uoa.gr/
176 http://www.go-lab-project.eu/
177 http://www.go-lab-project.eu/lab/international-space-station-3d-teaching-
tool
178 http://www.go-lab-project.eu/lab/discovery-space-portal
Endnotes and Links

European Commission & The New Media Consortium
EUR 26673 – Joint Research Centre – Institute for Prospective Technological Studies
Title: Horizon Report Europe: 2014 Schools Edition
Authors: Larry Johnson, Samantha Adams-Becker, Victoria Estrada, Alex Freeman, Panagiotis Kampylis, Riina Vuorikari & Yves Punie
Luxembourg: Publications Office of the European Union, & Austin, Texas: The New Media Consortium, 2014
2014 – 54 pp. – 17.6 x 25 cm
EUR – Scientific and Technical Research series – ISSN 1831-9424 (online) ISSN 1018-5593 (print)
ISBN 978-92-79-38476-9 (pdf)
ISBN 978-92-79-38477-6 (print)
doi:10.2791/83258
Abstract
The NMC Horizon Project from the New Media Consortium is a long-term investigation launched in 2002 that identifies and
describes emerging technologies likely to have a large impact over the coming five years in education around the globe. The NMC
Horizon Report Europe: 2014 Schools Edition, the first of its kind for Europe, examines six key trends, six significant challenges and
six important developments in educational technology that are very likely to impact educational change processes in European
schools over the next five years (2014-2018). The topics within each section were carefully selected by the Horizon Project Europe
Expert Panel, a body of 53 experts in European education, technology, and other fields. They come from 22 European countries,
as well as international organisations and European networks. Throughout the report, references and links are made to more than
150 European publications (reports, articles, policy documents, blog posts etc.), projects (both EU-funded and national initiatives)
and various policy initiatives from all over Europe. The Creative Classrooms multidimensional framework, developed by European
Commission’s JRC-IPTS on behalf of DG EAC, was used for analysing the trends, challenges and technologies impacting European
schools over the next five years. The analysis reveals that a systemic approach is needed for integrating new technologies in
European schools and impacting educational change over the next five years.

Interested in these topics? Learn more about them and other Horizon Project insights by
“liking” the NMC on Facebook at facebook.com/newmediaconsortium and on Twitter at
twitter.com/nmcorg. Access the European Commission on Facebook at facebook.com/
EuropeanCommission and on Twitter at twitter.com/EU_Commission.

LF-NA-26673-EN-N
doi:10.2791/83258
ISBN 978-92-79-38476-9 (pdf)

Horizon Report Europe. 2014 Schools Edition

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