ICT PEDAGOGICAL INNOVATIONS
1
INNOVATIVE MODELS OF PEDAGOGICAL IMPLEMENTATION OF ICT
IN ISRAELI SCHOOLS
David Mioduser, Rafi Nachmias, Dorit Tubin, and Alona Forkosh-Baruch
Tel-Aviv University, School of Education, Tel-Aviv, 69978, Israel
miodu@post.tau.ac.il
[final and revised version of this research report was published in:
Journal of Computer Assisted Learning, 18(4), 2002 - ”]
RUNNING HEAD: ICT PEDAGOGICAL INNOVATIONS
ICT PEDAGOGICAL INNOVATIONS
2
ABSTRACT
In the paper we analyze the data collected in ten schools in Israel which have incorporated
ICT in unique ways and have succeeded in devising innovative classroom pedagogies and
changes in teachers and students roles and outcomes. The major research questions
addressed are: (a) What levels of innovation were observed in the participant schools, and in
which domains? (b) How does the level of innovation in the various domains vary among
and within schools? (c) What correlation patterns among levels of innovation in the various
domains can be identified? The results of ten comprehensive case studies of exemplary
schools in Israel were analyzed by mean of the innovation analysis schema developed by us
for characterizing ICT-based educational innovations. The findings indicate that most
schools as such are in transition stage towards fully innovative pedagogical implementation
of ICT; school activities are effected differentially by ICT, thus creating "islands of
innovation"; these islands however have the potential to pull forward other areas of activity
and people in the school; the domains most affected by ICT are the school's "digital space",
the didactic solutions implemented, and the students' roles and outcomes; in contrast,
domains such as physical space, time configuration and professional interaction among
teachers were less affected; schools' and particular persons' vision and determination, and
students' drive for involvement and participation, are crucial factors in the development of
the innovations.
ICT PEDAGOGICAL INNOVATIONS
3
INTRODUCTION
A great deal of theoretical and empirical work has been done for several decades regarding
the impact of ICT on educational processes (for ample surveys of these research efforts see
Becker, 1994; Mioduser & Nachmias, 2002; Pelgrum & Anderson, 1999). The incorporation
of ICT into the school has affected its functioning at multiple levels: new configurations of
learning spaces and timetables have been created; innovative teaching methods were devised;
autonomous and active learning processes using the technology have been adopted; teachers’
traditional roles have been expanded, and include personal and group tutoring and guidance
functions; and new ICT-based curricular solutions have been generated.
In this paper we report the results of a study conducted as part of our involvement in two
international research projects on school innovation using ICT. One is the Second
Information Technology in Education Study (SITES) Module 2, by the IEA (Kozma, 2000),
and the other is the Case Studies of ICT and Organizational Innovation, sponsored by the
OECD, (OECD/CERI, 2000). Both studies concentrated on case studies of successful and
innovative implementations of ICT in about 30 countries. In Israel, we examined
comprehensively ten schools that have incorporated ICT in unique ways and succeeded in
devising innovative classroom pedagogies and school system changes (for a broad
description of the study and its results see Tubin et al., in press). The research questions
addressed were:
a) What levels of innovation, and in which domains, were observed in the schools?
b) Do levels of innovation vary among domains within a school?
c) What are the relationships among levels of innovation in the different domains?
ICT PEDAGOGICAL INNOVATIONS
4
METHOD
School selection procedure
To select the participating schools a preliminary list of about 100 cases (recommended by the
Ministry of Education, school networks, non-profit educational organizations, and
Universities) of innovative usage of ICT in schools was created. On the basis of information
collected about the schools, and the application of defined selection criteria, the study's
expert advisors panel together with the research team proposed the final list of candidates for
the case studies (in this paper the schools are referred to as ILxxx, eg, school IL001).
The selection criteria stated that an appropriate candidate is a school practice:
1. That shows evidence of significant changes in roles of teachers and students, the goals of
the curriculum, assessment practices, and/or the educational materials or infrastructure.
2. In which technology plays a substantial role.
3. That shows evidence of measurable positive student outcomes.
4. That is sustainable, transferable, and scalable.
5. That is innovative, as locally defined in each country.
Data collection tools
Eleven tools were designed by the international research group and adapted locally: principal
questionnaire; principal interview; computer-coordinator questionnaire; computercoordinator interview; administrator or supervisor interview; focus-group interview of
teachers involved in the innovation, and teachers not involved in the innovation; focus-group
ICT PEDAGOGICAL INNOVATIONS
5
interview of students involved in the innovation; focus-group interview of parents familiar
with the innovation; observations; learning products analysis.
Data collection process
Data was collected between December 2000 and June 2001 in ten schools, by a team
comprising nine researchers. Small teams of 2- 3 researchers visited the schools 3-5 times
spending altogether about 60 person-hours per school. A typical interview lasted about an
hour and a half, and was carried by one researcher. Classroom observations typically lasted
45 minutes and were held in pairs. All interviews were recorded and all observations were
written down. All data were transcribed into digital files and uploaded to the Israeli research
Website (http://muse.tau.ac.il/ict).
Data analysis
For the systematic analysis of ICT-based pedagogical innovations in the participant schools
we developed the innovations analysis schema (only a brief description of the schema is
presented here, for a more detailed description see Mioduser et. al, in press). The schema's
dimensions are defined by two axes. The horizontal axis represents levels of innovation,
ranging from preliminary alterations of the school’s routine due to the initial assimilation of
ICT, to far-reaching transformations of pedagogical practices and learning processes. Three
main levels were defined. The first level -assimilation- is the situation in which specific
pedagogical situations change qualitatively, but the school curriculum as a whole (e.g.,
content and goals), the instructional means (e.g., textbooks), the learning environment (e.g.,
classrooms, labs), and the learning organization (e.g., timetable) remain unchanged. The
ICT PEDAGOGICAL INNOVATIONS
6
second level -transition- is a situation in which ICT supports the integration, within the
school's everyday functioning, of new contents, didactic solutions, and organizational
solutions side by side with the traditional ones. In the third level -transformation- substantive
changes take place in the school system as a whole. Traditional processes still exist, but the
school identity is mainly defined by the rationale and goals of new approaches and lines of
operation; student and teacher roles are enriched with new dimensions; new contents are
introduced to the curriculum; new teaching methods are developed and implemented; and for
particular activities the traditional time and space configuration is transformed.
The vertical axis details domains of innovation, focusing on four main constituents of the
school’s milieu: time/space configurations, students, teachers, and the curriculum. Table 1
presents a summary of the innovation domains and levels in the innovation analysis schema.
------------------------------------------------------Insert Table 1 about here
------------------------------------------------------Two independent evaluators analyzed each case-study's data using the above schema. Each
evaluator came up with a scaling for each school in each domain on a 5-value scale: 1 - basic
assimilation level, 2 - beginning of the transition, 3 - transition level, 4- - beginning of the
transformation level and 5 - full transformation level (it should be noted that the analysis unit
in this study concentrates on specific innovative pedagogical practices using ICT within
schools, and not on the whole school). The evaluation resulted in 90 school-level-locations
(SLL), for 9 sub domains in 10 schools. Out of the 90 SLLs, matching judgment was
reached for 75 (83%) in the first evaluation round. The remaining 17% were discussed and
elucidated by the evaluators and other members of the research team, until full agreement has
ICT PEDAGOGICAL INNOVATIONS
7
been reached. The final results of the scaling was analyzed in various ways as presented in
this paper.
RESULTS
The study results are reported here according to the research questions, namely levels of
innovations in schools, characteristics of innovations in schools, and relationships among
levels of innovation in the diverse domains.
Levels of innovations in schools
The ten schools presented in this study were chosen because they were considered as
successful examples of “using ICT for pedagogical practices in an innovative way”. Yet, the
question remains whether and how this innovation is reflected in some or all domains of the
school's activity. Table 2 presents the distribution of the Israeli schools by level of
innovation for each domain.
------------------------------------------------------Insert Table 2 about here
------------------------------------------------------Data indicate that most schools, in most of the innovation domains, are at the transition level
(65 out of the 90 SLLs - 72%), and only in few domains (17 SLLs -19%) they reached the
transformation level. Taking into account that the ten schools were selected as models for
innovation, this distribution shows a different pattern than expected. Specific data by domain
follows.
ICT PEDAGOGICAL INNOVATIONS
8
Time and space configurations
Physical space. In general, the classroom walls remained intact. Eight out of the 10 schools
are in the assimilation and transition levels, being their computers located in public spaces
(e.g. computer room, laboratory). The two remaining schools are in the transformation level.
For example, in school IL003 the building was designed from scratch in an innovative and
technology oriented approach, integrating massively ICT facilities in all learning spaces (see
description in a later section).
Digital space. Most of the schools are located in the transition level and beyond. For
example, several schools have developed Websites serving as online news board, as portals
to dynamic learning centers, or as virtual gateways to Websites all over the world.
Time configuration Schools at the assimilation level incorporate ICT activities within their
structured schedule and timetable. One example is school IL008, which operates 13 virtual
courses embedded in the regular timetable. At the transition level, periods are organized in
time-blocks within which the students are free to use the computer for their needs (e.g.,
students acting as computer trustees are allowed to skip regular lessons for completing their
computer assignments). Five schools located at the highest levels of innovation showed a
fairly flexible organization of time. For example, high school IL006 allows its students at the
radio division to use ICT and work on their radio programs during the school day and
beyond, till late afternoon, according to their needs.
ICT PEDAGOGICAL INNOVATIONS
9
Student role
Most of the innovative practices (6 out of 10) cause a significant change in student role, who
became Website constructors, teachers' assistants in ICT-related matters, or ICT projects
managers. For example, in High school IL009 the students worked in teams to solve real
problems and to accomplish projects invited (and funded) by local High-tech companies.
Teacher role
Teacher/student interaction. Schools that were in the transition level and beyond showed
interesting changes in teachers' role. For example, in High school IL007, teams of teachers
and students work together in developing Websites in about 20 subjects, which would serve
the ongoing teaching and learning in the school. This interaction eventually makes the
teacher more familiar with the technology, and the students more knowledgeable with the
subject under study.
Teacher/teacher interaction. In 8 out of 10 innovative practices the relationship among
teachers are in transition level and below, showing only limited team work and collaboration.
Curriculum change
Content. ICT use affects curricular contents in diverse forms. In 4 schools in which the
innovative practices pertain to the transition level or below, ICT supported only a sort of
expansion of the traditional subjects. At the transformation level, schools used ICT for
dealing with new subjects. For example students in high school IL013 developed a
comprehensive Website about the salt flat near to which their regional school is located, and
ICT PEDAGOGICAL INNOVATIONS
10
collaborated with Jordanian students working on contents and issues related to the shared
natural phenomenon (see description in a later section).
Didactic solutions. Most of the innovations observed pertain, regarding didactic practices, to
the transition level, e.g., the use of digital worksheets stored in Websites to practice earlier
studied topics, or searching the Internet for information to be used in class. At the
transformation level the learning activities are qualitatively upgraded by the use of ICT. For
example, in the greenhouse at High School IL015, the students engage in research projects
dealing with real problems like fish nutrition or water contamination (see description in a
later section).
Assessment methods. In school innovations at the assimilation level ICT is implemented in
traditional fashion. Innovations located at the transition (3 schools) and transformation (5
schools) levels, included the use of novel assessment procedures such as polls, Websites
design contest, or digital portfolios.
Characteristics of innovations in school
Although all schools in this study are innovative in a particular way, they differed from each
other in many aspects. In this section we examine how the levels of innovation in the
different domains are distributed within schools. Table 3 presents the level of innovation for
all schools in all nine domains. For each school, two coefficients were calculated: the first is
school overall level of innovation (calculated as an average of levels for all domains). The
second coefficient is a measure of deviation of the nine domains from this average (SD).
ICT PEDAGOGICAL INNOVATIONS
11
The variation in innovation level among all innovative practices suggests that ICT
implementation is a process, and different schools can be performing at different stages of
this process. The deviation of the level of innovation per domains within each school
indicates that the innovative pedagogical practices have a differential impact on the diverse
domains. In some of the schools the innovation level is homogenous (similar records for all
domains), while in others it is very heterogeneous. This coherence can be observed at any
location in the innovation level scale, e.g., IL002's innovative practice is consistently located
in all domains slightly below the transition level, and IL015 coherently located at the
transformation level.
------------------------------------------------------Insert Table 3 about here
-------------------------------------------------------
Correlation among domains of innovation
The third research question relates to the degree of correlation (Table 4) among innovation
levels in the diverse domains (it must be noted that only ten schools are being analyzed,
implying that the correlation indices and their significance should be viewed primarily as an
indication of general trends).
------------------------------------------------------Insert Table 4 about here
------------------------------------------------------Changes in student role and in the nature of teacher/student interactions are highly correlated
with changes in time and digital space configurations, and with new didactic solutions. In
ICT PEDAGOGICAL INNOVATIONS
12
the case of teacher/teacher relationships, most correlations with other domains are very low,
suggesting that the innovative practices have had little influence in teachers’ communication
and work patterns. The curriculum-related domains usually correlate moderately and high
with each other and with the rest of the domains, indicating that innovative practices
compromise the curriculum in a systemic way, bringing about changes in all its components.
Of all the domains, didactic solutions was the one with the highest correlation with nearly all
other domains (except teacher/teacher interaction), indicating that this is the central domain
of the educational innovative practices.
Examples of distinctive models of innovation in different domains
In this section we describe examples of practices in specific schools, which illustrate unique
aspects of the innovations in different domains.
Innovation in students' role: Computer trustees
The innovation in school IL002 is based on the involvement of students in leading the
process of ICT implementation within the school. The students act as tutors for the school
staff in teacher-training courses, assist them in lessons in which ICT is implemented, and in
preparing lesson plans. They act in a number of circles outside the school as well. They have
adopted a special education school where the trustees train students to use the computer, to
edit presentations, to search the Internet and to download learning materials. They also run
“The Inter-Generation Connection” training senior citizens in surfing the web, using e-mail
and ICT in general. The activities supply the senior citizens a communication channel, as
well as learning skills and enrichment in their leisure time. As posted in the inter-generation
ICT PEDAGOGICAL INNOVATIONS
13
online forum: “I learned new things regarding the computer, and I reached a conclusion that
there is no end to studying.” (Lady senior citizen), “When I returned from abroad, my first
time out was for the computer course, and I felt that I did come back home.” (Lady senior
citizen).
The core innovation of the trustees project is that it allows students to play an authentic and
substantial role in the school's community. Students play commonly the (passive) consumers
role in the school system. In some occasions they are given the possibility to play other roles
(e.g., history trial, or one-day student-ruling of the school), but these are mostly simulation
exercises and not real-life tasks. In the trustees project the students are considered valuable
human resources within the school community, as owners of knowledge which has authentic
meaning for others inside and outside the school.
Alternative space, alternative time, alternative curriculum: The computerized
Greenhouse
The computerized greenhouse is an exceptional learning environment functioning in a
kibbutzim regional school, since the 80's. About 15 years ago the greenhouse was
computerized, and ICT became an integral part of its functioning and of the learning
activities in it as well. Every year, about 50-70 students plan and carry out projects in
biology, technology, ecology and agriculture as part of their high school matriculation
studies. The greenhouse works as an autonomous organization. It is run by a team including
the director (a graduate of arts and a conceptual artist) and a few part-time instructors and
assistants (students) who coordinate the different fields (fish, plants, water, ICT). In
addition, there are first-class experts from research institutes and the ministry of agriculture
ICT PEDAGOGICAL INNOVATIONS
14
who instruct the students in their research. The activity hours are every day within and after
school hours, sometimes till late evening.
To explain the model according to which the greenhouse works, the director draws a triangle
in which one of its sides is education, another research and experimenting and the third is art
and innovation. The greenhouse integrates all 3 domains, and this is what creates the special
atmosphere on the one hand, and the flexibility and adaptation of the greenhouse on the
other. “The model I believe in is the creation of islands outside the school, that can sustain
themselves financially … for example, they could find contacts with certain high-tech
companies, or with people who will be willing to invest.”
A 12th grade student who spent the last 5 years at the greenhouse, commented on the learning
atmosphere: “this is nothing compared to the classroom,” [This is a place where] “you don’t
just come, take your measurements and leave with your log, like in other schools. Here
there’s brotherhood, love, it’s fun to work here with the people. I, for instance, am in charge
of the whole fish team. If 8th grade students come, and the fish topic will interest them, I’ll
push them towards it, I’ll get them into it, I’ll want them to take care of the fish after me,” .
The greenhouse allows students to be involved in authentic learning projects (with real
scientific, technological and economical value), in a temporal/spatial/social/curricular
configuration that represents a highly innovative alternative to traditional schooling.
Systemic school design and implementation: School of the Future
IL003 is one of ten schools in Israel founded by the Ministry of Education in the 90's to
examine innovative educational models. It was planned and built as advanced schooling
ICT PEDAGOGICAL INNOVATIONS
15
model, according to an educational concept that views ICT as a means for empowering and
redefining the relationship between students and knowledge, for facilitating learning skills
acquisition, and improve academic achievement. As one of the teachers reported: “Since the
school from its very beginning was enriched by computers, it would be very difficult without
them, because half of the curricula is computer-based.” … “Without the computers, this is a
different school…”
The innovation of the school is in its holistic perception and integration of several
components: the physical structure and organization (including architectural design)
supporting the pedagogical approach; professional teams that develop and adapt curricula;
the organization into two-year "homes" (instead of regular classes); the implementation of
ICT in almost all disciplines; a variety of teaching and learning methods; an emphasis on self
studying and student responsibility; the use of alternative assessment, such as portfolios and
projects – all these are an integral part of and support the innovation. At the end of the 6th
grade the school tests the students’ mastering of computer skills.
The school “homes” are spaces for about 75 students of double-age grades (kindergarten to
1st grade, 3rd to 4th grade, 5th to 6th grade), taught and administrated by a staff of 2-3
members. In each home there are 3 studying environments: the open space teaching area, the
computer gallery, and the mini-auditorium. Learning takes place in each environment
according to the subject and the assignments. ICT-supported learning processes are
performed throughout the day, covering about 30% of the lessons. This structure demands
intensive teamwork for the planning and implementation of the curricula. Most of the
ICT PEDAGOGICAL INNOVATIONS
16
communication between staff members is through e-mail, and all didactic materials are
stored in electronic databases.
The academic advisor of the whole project assesses: “Maybe the most evident achievement is
that the teachers have become a learning community… not only students, but also teachers
learn in this school all the time… The school norms have become academic in nature, in that
you can inquire about anything, doubt anything, you have to work hard, prepare and plan,
keep track of processes via documentation and explain steps you take. It is not an ideal place,
it has human weaknesses.”
Curricular innovation: "Humans and their surroundings" Websites
One of school IL015's main goals is fostering an independent learner. Special emphasis is
put on project-based activities, alternative evaluation, and independent studies. As the
principal (a Geologist) explains: "the students begin with a personal project in grade 1, and
end with their final project in grade 12… in a variety of contents, and at different skill
levels".
A central curricular project in the school is its continuously developing Website, conceived
as a dynamic learning center for the whole school. This Web learning center contains
projects by students, a bank of geographical and historical textual and visual materials,
learning activities, links to relevant Websites, and sections for special education and
immigrant students. A special component in it is the collaboration between the school's and
Jordanian students from the village of Rah'me, around the topic of the nearby salt flat. The
international border divides the salt flat between Jordan and Israel. This represented the
opportunity to work together, also (but not only) using ICT, in issues related to the shared
ICT PEDAGOGICAL INNOVATIONS
17
natural phenomenon. As phrased by a teacher: "if we can not go now to Jordan, by pressing
a key we can bring peace closer".
According to the principal, one of the reasons why the school became "a good place to be
to", are the numerous projects running at the same time (e.g., purely academic such as the
Website construction, social as the absorption of the Ethiopian students, or cultural as theater
or music groups). "Some teachers call me 'a community center director', but I have no
problem with that. I believe that is the way one should work. With all the respect to us as
teachers, there are many situations at which students learn a lot by themselves without our
intervention, and we should facilitate these situations in school. Computers are an excellent
example".
DISCUSSION
The extent to which ICT implementation in education has affected the structure and
functioning of schools, pedagogies in use, contents being taught, or learning achievements,
has been a matter of controversy over the years (e.g., Cuban, 1986; Schank & Yona, 1991).
However in practice, numerous successful examples of innovative ICT uses for teaching and
learning are found all over the world (Mioduser et. al. 1999; Voogt & Odenthal 1999,
Venezky & Davis, 2002). Here we elaborate on our findings in ten Israeli schools, as part of
our participation in the IEA's and OECD's international studies.
A first overall observation is that most practices in the participant schools, for most domains
(and sub domains) considered, occur in the transitional-towards-transformational level.
Taking into account that the ten schools were selected as models for innovation, a complete
ICT PEDAGOGICAL INNOVATIONS
18
transformation in most aspects could be expected. However, the findings show that the
assimilation and diffusion of ICT-based innovations within schools is a complex and gradual
process, even under the most favorable conditions (e.g., highly motivated leaders,
infrastructure, human and financial resources).
Not all areas of activity in the school are affected in similar way. Usually resources and
efforts are allocated mainly to foster the innovation's goals in a defined area (e.g., a subject, a
specific population, a novel pedagogical configuration). As a result, in nearly all schools
significant changes took place mainly in those sub-domains that were relevant to the
innovations focus.
Our findings indicate that the domains "digital space" and "didactic solutions" underwent the
most significant changes by the implementation of ICT. Next to be affected were the student
role, the teacher/student interactions, and the assessment methods. Less affected by the
innovations were the physical space and time configuration, the content areas and the
interactions among teachers. An important conclusion can be drawn from these
observations: the main beneficiaries of the innovations studied were the students. The
innovations implied for them new roles, learning situations, patterns of interaction with the
teachers, learning spaces, and forms to be assessed.
A central conclusion of the study relates to the type of relation existing between the
innovation and the school's context. In many schools, the observed practices appeared to be
"islands of innovation", clearly discernible in the surrounding sea of traditional practices. In
these schools the innovation is driven by a small but highly motivated group (from within
and outside school), with explicit support of the principal. However, in a few schools the
ICT PEDAGOGICAL INNOVATIONS
19
studied practice was a part of an intricate web of innovative projects. In these schools the
encouragement of innovations is embedded in explicit vision and policy, and staff and
students are committed to its implementation.
Finally, a few words on the continuation of our investigation of the case studies. First, there
is the work with the international database (about 200 cases in about 30 countries) enabling
the examination of questions that are beyond the scope of the present paper (e.g., major
trends evolving in the various domains, the role of cultural and contextual factors or national
policies in the development of the innovative practices). The second line of planned work
will focus on the identification and close examination of the whole set of factors (e.g., human
resources, infrastructure, staff training, policy, outside-school agents) affecting the
emergence and sustenance of innovative practices in schools.
In spite of the particular features of educational systems that make them more resistant than
other social systems to the adoption of innovations and change, and in spite of the skeptical
voices questioning the very need to promote the integration of ICT into teaching and learning
process, there is no doubt that there are clear signs of change in countless examples from
schools worldwide (Venezky & Davis, 2002). It is fairly clear that these are times of
transitions both for technology and pedagogy (Dede, 1996). Our role as researchers is to
accompany these exciting processes, shed light on the factors for success and failure,
recognize evolving trends, and help to devise new and improved pedagogically sound
practices using ICT.
ICT PEDAGOGICAL INNOVATIONS
20
BIBLIOGRAPHY
Cuban, (1986). Teachers and machines: The classroom of technology since 1920. New York:
Teachers College Press.
Dede, C. (1996). Emerging technologies and distributed learning. The American Journal of
Distance Education, 10(2), 4-36.
Kozma, R. (2000). Qualitative Studies of Innovative Pedagogical Practices Using
Technology. SITES M2 design document, IEA.
Mioduser, D., & Nachmias, R. (2002). The WWW in education: An overview. In H.
Adelsberger, B. Collis, & J. Pawlowski (Eds.). Handbook on Information Technologies
for Education and Training. Springer-Verlag
Mioduser, M., Nachmias, R., Lahav, O. & Oren, A (1999). Web-based learning environments
(WBLE): current implementation and evolving trends. Journal of Network and Computer
Applications, 22(4), 233-247.
OECD/CERI (2000). Schooling for Tomorrow, Methodology for Case Studies of
Organizational Change.
Pelgrum, W., & Anderson R. (Eds.) (1999). ICT and the emerging paradigm for Life Long
Learning: a worldwide educational assessment of infrastructure, goals, and practices.
Amsterdam: IEA.
Schank R., & Yona, M. (1991). Empowering the student: New perspectives on the design of
teaching systems. Journal of the Learning Sciences, 1, 7-36.
Tubin, D., Mioduser, D., Nachmias, R., and Forkosh-Baruch, A. (in press). Domains and
levels of pedagogical innovation in schools using ICT: Ten innovative schools in Israel.
Venezky, R. & Davis, C. (2002). Quo vademus? The transformation of schooling in a
networked world. Preliminary research report: OECD/CERI.
ICT PEDAGOGICAL INNOVATIONS
21
Table 1: Levels and domains of pedagogical innovation using ICT
Levels
Domains
Time
and
space
configuration
Student
Role
Teacher
Role
Curriculum
Assimilation
Transition
Transformation
Physical
space
Public spaces
Public and personal
spaces
Personal and community
spaces in school and
Beyond
Digital
space
Desktop and Internet
applications usage
Flexible Internet use and
content creation
Virtual learning spaces
and organizations
Time
Mainly embedded in the
schools schedule and
timetable
Flexible access for
individuals within
constraints of school’s
schedule
Any time for all in school
hours and beyond
Main roles
Using ICT for
accomplishing curricular
assignments
Development of ICT
generic expertise – for
usage, maintenance, and
creation
Personal assimilation of
ICT as learning, creation
and working means
With
students
Main source of leadership,
information, and
knowledge.
Pedagogic authority,
mentor, supporter,
coordinator
Expert colleague, partner
to the process of
discovery.
With
teachers
Acting individually,
functional peer interaction
Team work,
collaboration, mutual help
Acting cooperatively,
organic solidarity
Content
Traditional subjects
enriched with ICT
Expanded subjects
incorporating new
knowledge resources
New subjects; Design and
development using ICT.
Didactic
solutions
Tutorial packages,
constrained use of generic
tools and Internet
Open assignments and
projects using generic
tools and Internet
Virtual environments,
development of personal
digital spaces.
Assessment
methods
Digital versions of
standard assessment means
Criteria development for
assessing digital products
Digital alternative
assessment: projects,
portfolio, etc.
ICT PEDAGOGICAL INNOVATIONS
22
Table 2: frequencies of Israeli innovative practices by innovation level and domains (n=10)
Levels
Domains
Physical
space
Time
and
space
configuration
Digital
space
Time
Student
Role
Main roles
With
students
Teacher
Role
With
teachers
Content
Curriculum
Didactic
solutions
Assessment
methods
Assimilation
Transition
Transformation
ICT PEDAGOGICAL INNOVATIONS
23
Table 3: Schools levels of innovation
School
IL001
IL002
IL003
IL006
IL007
IL008
IL009
IL010
IL013
IL015
Physical
space
3
1
5
2
2
1
3
1
3
5
Digital
space
3
2
3
4
4
3
4
3
5
5
Time
1
3
4
4
3
1
3
4
5
5
Main roles
2
3
4
4
4
2
4
3
4
5
With
students
3
3
3
4
3
2
4
4
5
5
With
teachers
3
1
5
2
3
3
3
3
4
2
Content
3
2
5
4
2
3
5
4
5
5
Didactic
solutions
3
2
4
3
3
2
3
3
5
5
Assessment
methods
3
1
4
4
3
3
4
1
4
5
School average level of
innovation
2.7
2.0
4.1
3.4
3.0
2.2
3.7
2.9
4.4
4.7
School deviation of
domains
0.7
0.9
0.8
0.9
0.7
0.8
0.7
1.2
0.7
1.0
Domains
Time
and
space
configuration
Student
Role
Teacher
Role
Curriculum
ICT PEDAGOGICAL INNOVATIONS
24
Table 4: Correlation matrix of the innovation domains (N = 10 schools)
!
Physical
space
Physical Digital
space
space
Time
Student Teacher Teacherrole
student teachers
Content
Didactic Assesssolutions
1
Digital
space
0.49
1
Time
0.43
0.58
1
Student role
0.60
0.71*
0.85**
1
Teacher student
0.41
0.76**
0.83**
0.71*
1
Teacher teachers
0.44
0.17
0.09
0.05
-0.04
1
Content
0.67*
0.58
0.61
0.56
0.67*
0.47
1
Didactic
solutions
0.78**
0.78**
0.75*
0.70*
0.78**
0.41
0.73*
1
Assessment
0.77**
0.77**
0.32
0.60
0.42
0.32
0.64*
0.67*
* p < 0.05,
ment
**p < 0.01
1