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Australasian Journal of Educational Technology, 2013, 29(4). ascilite 
 

 480 

Interactivity with the interactive whiteboard in traditional and 
innovative primary schools: An exploratory study  
 
Sandra de Koster 
VU University Amsterdam, the Netherlands 
 
Monique Volman and Els Kuiper 
University of Amsterdam, the Netherlands 
 
 

One of the main affordances of the interactive whiteboard (IWB) is its potential for 
increasing classroom interactivity, yet little is known about the interactivity it supports in 
schools with different educational concepts. In this study we analysed what types of whole-
class interactivity the IWB supports in schools with either a traditional or an innovative 
school concept. Interactivity was operationalized in terms of operation of the IWB, control 
of the IWB content, and the whole-class dialogue. A cross-case analysis of videotaped 
lesson observations revealed patterns in the interactivity related to school type. Comparison 
of the prevalent interactivity patterns at the two school types shows that students at the 
innovative schools had a more active role in the content of the IWB-supported lessons than 
those at the traditional schools. The students at the traditional schools operated the IWB 
more often, which coincided, however, with little or no student control of the IWB content 
and with whole-class dialogue that focused on knowledge transmission. At the innovative 
schools the active student role regarding lesson content did not coincide with student 
operation of the IWB. These findings indicate a link between the school's educational 
concept and the type of interactivity in IWB-supported lessons. 

 
Introduction 
 
Over the past decade the interactive whiteboard (IWB) has proved to be a valuable tool for teaching and 
learning. Earlier research on the use of the IWB as a pedagogical tool mainly explored the potential it 
might hold for education, as Glover, Miller, Averis, and Door (2005) show in their literature review. 
More recent studies focus on the advantages and disadvantages of the IWB as an educational tool (Cutrim 
Schmid, 2008; Slay, Siebörger, & Hodgkinson-Williams, 2008; Somyürek, Atasoy, & Özdemir, 2009) or 
investigate how the IWB is actually being used in pedagogical settings (Smith, Hardman, & Higgins, 
2006; Haldane, 2007; Kershner, Mercer, Warwick, & Staarman, 2010). 
 
Findings suggest that the IWB can be used to support different types of classroom interactivity. Although 
Smith et al. (2006) find in their study that the IWB is mostly used for whole-class teaching with a 
relatively high pace and frequent yet short student answers, other studies show that it can support both a 
teacher-directed and a more student-directed pedagogic approach to whole-class teaching (Gillen, Kleine 
Staarman, Littleton, Mercer, & Twiner, 2007). In this study we investigate what types of interactivity 
occur in IWB-supported lessons in schools with either a teacher-directed pedagogy or a student-directed 
pedagogy. 
 
Classroom interactivity supported by the IWB 
 
After the introduction of the IWB into the classroom arena, most studies focused on the use of the IWB to 
support whole-class lessons (Kershner et al., 2010). More recent studies focus on the use of the IWB in 
individual and group work by students as well, for instance in collaborative tasks in which children share 
ideas about a topic (Kershner et al., 2010; Warwick, Mercer, Kershner, & Kleine Staarman, 2010).  
 
Its potential for supporting classroom interactivity is one of the main reasons given by teachers for 
adopting the IWB (Smith, Higgins, Wall, & Miller, 2005; Kennewell, Tanner, Jones, & Beauchamp, 
2008). In the analysis of classroom interactivity supported by the IWB it has become customary to take 
both the technical and the pedagogical dimensions of the interactivity into account (cf. Smith et al., 2005; 
Kennewell et al., 2008). The technical dimension of interactivity – often referred to as technical 
interaction – relates to the operation of the board by the teacher and/or students, like browsing the internet 



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or showing and processing images or text (writing, drawing, dragging, clicking, et cetera). The 
pedagogical dimension of the interactivity – or pedagogical interaction – on the other hand encompasses 
all elements of the interactivity among teacher and students (or among students) that serve a pedagogical 
purpose (Smith et al., 2005; Evans & Gibbons, 2007). This dimension includes the teacher's pedagogical 
decisions that relate to technical interactions with the IWB, like whether or not to give students the 
opportunity to operate the board or to have control of the content on it. It also includes classroom 
dialogue about subject matter. 
  
Interactivity in different models of learning and instruction  
 
In the literature we find high expectations of how increased interactivity can engage students in their 
learning process in a more active way (cf. Beauchamp & Kennewell, 2010). One of the rationales behind 
these expectations is the assumption that actively engaged students have a higher learning motivation, 
which increases learning results (Beeland, 2002; Torff & Tirotta, 2010; Hennessy, Deaney, Ruthven, & 
Winterbottom, 2007; Slay et al., 2008). Another rationale is the assumption that learning by definition 
implies a process of knowledge construction in which the student plays an active role (Jonassen, 1992; 
Mayer, 2001). 
 
Classroom dialogue is one of the key aspects of classroom interactivity (Wells & Arauz, 2006). In 
classroom dialogue it is traditionally the teacher who initiates the exchange and takes on the role of 
didactic expert (Smith et al., 2006) or "primary knower" (Nassaji & Wells, 2000, after Berry, 1981). The 
teacher transmits information through lectures. Subsequently the teachers' questions in this type of 
dialogue are primarily aimed at recitation of previously memorised information. Students' responses are 
evaluated in terms of correctness or conventionality (Mroz, Smith, & Hardman, 2000). This division of 
roles reflects the traditional division of power between teacher and students (Lemke, 1990), also 
associated with the instructional model of knowledge transmission. Nassaji and Wells (2000) point out 
that control is divided more equally if the teacher does not claim the role of didactic expert or primary 
knower. In that case the teacher asks more open questions and focuses on promoting understanding rather 
than transmission and recitation of information. This approach rather reflects the instructional model of 
knowledge construction (Rogoff, 1994).  
 
Thus the nature of classroom dialogue and hence classroom interactivity appears to vary with the model 
of learning and instruction that underpins the learning activity in which the interactivity occurs. As the 
IWB can be used in very diverse pedagogical ways (Winzenried, Dalgarno, & Tinkler, 2010) it can 
reasonably be expected to support different types of interactivity in schools with different educational 
concepts.  
 
Concept-guided development of ICT use 
 
Research shows that a significant condition for the successful integration of information and 
communication technology (ICT) into the classroom is that the intended ICT use fits the school's 
educational concept. Zhao, Pugh, Sheldon, and Byers (2002) in this respect mention the importance of a 
minimal distance between an ICT innovation and the school's culture, i.e., the school's "dominant set of 
values, pedagogical beliefs and practices", while Tolmie (2001) points at the fit between the ICT 
resources that are used and the school's "established patterns of activity". Niederhauser and Stoddart 
(2001) stress that teachers are inclined to apply technology in a manner that is consistent with their 
"personal perspectives about curriculum and instructional practice". Developing ICT use in a "concept-
guided" way promotes this fit between pedagogy and technology (de Koster, Kuiper, & Volman, 2012). 
Concept-guided development implies that the school's existing concept is clarified and that possibilities 
are explored to develop ICT use that supports this concept. By concept we mean a school's classroom 
practices (cf. patterns of activity) and the educational views (values, beliefs, and perspectives) 
underpinning these practices. 
 
A previous study (de Koster et al., 2012) showed that this approach leads to clearly distinguishable types 
of ICT use, in line with the type of education that the school is aiming to provide. It is, therefore, to be 
expected that when schools develop their ICT use in a concept-guided way, the use of the IWB for 
supporting classroom interaction will vary according to the school's educational concept.  
 



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Method 
 
The four schools in this study participated in a project in which ICT use was developed in a concept-
guided way. The participating schools, classified as either traditional (mainly teacher directed) or 
innovative (mainly student directed), each developed a number of ICT-rich learning arrangements in a 
concept-guided way. Each school type developed a distinguishable type of ICT use (de Koster et al., 
2012). However, one tool that was included in learning arrangements across the school types was the 
IWB. As the IWB can be expected to support different types of interactivity in schools with different 
educational concepts, this aspect of IWB use became the focus of our investigation. So far the types of 
interactivity supported by the IWB in schools that develop their use of the IWB in a concept-guided way 
had not been investigated.  
 
The main research question for this study was: What types of classroom interactivity does the IWB 
support in traditional and innovative schools that develop their ICT use in a concept-guided way? 
 
Classroom interactivity in this context refers to all pedagogical interactions in whole-class situations, both 
with the IWB and in teacher-student dialogue. We focus on whole-class lessons, as the schools in this 
project all primarily used the IWB to support whole-class teaching. 
 
Participants and setting 
 
The four schools in this study participated in a project in which they developed ICT use in a concept-
guided way. The participating schools had educational concepts that were labelled as either traditional or 
innovative. The traditional label refers to a fixed curriculum and a strongly teacher-directed approach, 
while the innovative label indicates a more open curriculum with a focus on self-regulated learning.  
 
Of each school type two schools are represented in this study. The two traditional schools follow a mainly 
textbook-driven curriculum, with relatively little input from the students. Whole-class, direct instruction 
is the main form of instruction. After instruction, pupils individually or in pairs process the lesson content 
in highly structured exercises and assignments. The two innovative schools have a more open curriculum. 
Students at these schools have more input in learning content and activities, often working on research 
projects that start from their own research questions. Whole-class instruction is less predominant; students 
typically spend most time working in small groups or individually, while the teachers often take on a 
coaching role. 
 
Video observations of six lessons in six different classes across both school types were analysed. Each 
analysed lesson took place in the context of a different learning arrangement. The lessons were given by 
five different teachers; of one teacher two different lessons in two subsequent school years were analysed. 
The grade levels varied from second to sixth grade. Class sizes varied from 13 to 28 students.  
 
Procedure and design 
 
In the course of two school years the schools in this study each designed, developed and implemented up 
to four ICT-enhanced learning arrangements. The schools developed these learning arrangements in a 
concept-guided way, meaning that a team of teachers at each school was supported in designing and 
implementing learning arrangements in line with their school's educational concept (cf. de Koster et al., 
2012). The teachers were supported by educational counsellors specialised in guiding innovation projects. 
With these counsellors the teachers reflected on their school's educational concept and its ambitions for 
intensifying its use of ICT in line with this concept. This way we expected the schools' educational 
concepts to be reflected in the resulting ICT-enhanced learning arrangements.  
 
Data collection  
 
Several lessons in each learning arrangement were observed and in most cases recorded on video. For this 
study we selected three videotaped lessons per school type that were likely to give a meaningful and 
comprehensive picture of the IWB practices at the different school types. Most IWB-supported lessons 
mainly comprised whole-class interactions between teachers and students. We selected lessons that 
included a considerable amount of dialogue between teacher and students in order to study these whole-



Australasian Journal of Educational Technology, 2013, 29(4). 

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class interactions. The lessons were divided into episodes – i.e., clearly distinguishable parts, divided by 
for instance a change of topic – of which only the whole-class episodes were analysed. This led to an 
analysis of eight whole-class episodes for each school type, 2 to 20 minutes long and with an average of 8 
minutes per episode. A total of 128 minutes of observation footage was analysed. Relevant episodes of 
group or individual work by students are briefly described as part of the context.  
 
Microanalysis: types of IWB-supported interactivity 
 
We performed a microanalysis of the interactivity in the six lessons that were selected, in order to find 
patterns that would help characterise the interactions in IWB-supported lessons. For this microanalysis all 
whole-class interactions in the selected episodes were transcribed, including all content-related whole-
class dialogue and all technical interactions with the IWB. During the analysis we noted down the 
following characteristics of each lesson: the subject of the lesson, the grade and the lesson outline, 
including the general goal of the lesson (covering new subject matter or repeating previously covered 
content, et cetera), and the main content on the IWB. These aspects functioned as the context necessary 
for the interpretation of the interactions (Green & Dixon, 2002). 
 
With regard to the interactions with the IWB we distinguished two aspects:  
1. Operation of the IWB: who operated the board? Either the teacher exclusively operated the IWB 

(labelled as teacher), or the teacher let one or more students operate the board (student) or both 
teacher and student(s) operated the board (shared).  

2. Control of the content on the IWB: who decided what was written or shown on it? Possible values 
are teacher if the students had no input in the content on the IWB (e.g., the teacher did not ask for 
contributions or did not write down students' contributions), student if all content was provided by 
the students (e.g., only the students' contributions were written on the board), or shared in all other 
cases. 

 
The dialogue was described in terms of the teaching and learning model apparent in the dialogue. This 
could be labelled as either knowledge transmission (i.e., the teacher primarily transmits information 
and/or prompts students to recite previously transmitted information) or knowledge construction (i.e., the 
teacher tries to induce students to think actively and construct knowledge, focusing on understanding 
rather than recitation).  

 
In a cross-case analysis these descriptions were compared in order to find possible patterns of interactivity 
per school type (Miles & Huberman, 1994). Reliability of both the fragmentation and the analysis was 
ensured by the creation of an audit trail and discussion of the data with co-researchers to check for 
agreement (Graneheim & Lundman, 2004). 
 
Results 
 
In this section we discuss our findings on the types of IWB-supported classroom interactivity. The lessons 
at the traditional schools are discussed first, followed by a discussion of the lessons at the innovative 
schools. Each of the three aspects of interactivity (IWB operation, control of IWB content, and dialogue) 
is described and illustrated with exemplary excerpts from the observation transcripts. We conclude this 
section with a comparison of the results of both school types. 
 
Interactivity in IWB-supported lessons at the traditional schools 
 
Descriptions of the lessons analysed  
Lesson 1 consisted of two episodes. In episode 1a the teacher went over spelling rules that had been 
covered in an earlier instruction lesson and asked some students to do an exercise on these rules on the 
IWB. In episode 1b the teacher went through some exercises as a preparation for the students' individual 
work in their exercise books.  
 
Lesson 2 was divided into three episodes. In the first episode (2a) the teacher asked the class to compare 
two similar texts on the IWB. She then asked a student to show on the IWB how he would look for 
certain information on a specific webpage (2b). In the third episode (2c) the teacher asked this student and 



Australasian Journal of Educational Technology, 2013, 29(4). 

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some other students to type the information they found in their own words in a Word document displayed 
on the IWB. The teacher herself typed the final sentence, formulated with the students. 
 
Lesson 3 also comprised three episodes. In the first and third episodes (3a and 3c) the teacher discussed a 
task card that was projected on the IWB. In the second episode (3b) she discussed the outcomes of an 
exercise from the card with the class.  
 
Table 1 summarises the contextual characteristics of the lessons at the traditional schools. 
 
Table 1  
Lessons at the traditional schools: Context information 

Lesson School Grade(s) Subject Lesson outline Main content on IWB 

1 A1 3 Language Going over previously 
learned linguistic rules 
again and doing exercises 

Exercises from students' 
exercise books and exercises 
prepared by the teacher 

2 A1 3 Science Discussion of internet 
searching in the context of 
assignments on finding and 
processing information 

Two prepared texts, a 
webpage and text written by 
students 

3 A2 2 Science Introduction of a system of 
task cards as part of a new 
science method 

Teacher shows a task card 

 
Interactivity patterns 
Table 2 shows that at the traditional schools the IWB was operated by the teacher in five of the eight 
episodes, while in three episodes the operation was shared by teacher and students. With regard to the 
control of the content on the IWB, we found that in seven episodes the teacher fully controlled the 
content, while in one episode the control was shared. The dialogue in the lessons at the traditional schools 
reflected knowledge transmission as the main goal in five episodes, while in three episodes the dialogue 
was aimed at knowledge construction. The interactivity is summarized in Table 2 and is described in 
more detail below. 
 
Table 2  
Overview of interactivity patterns per aspect at the traditional schools 

Lesson Episode Operation of IWB Control of IWB content Type of dialogue 

1 a Shared Teacher Transmission 

 b Teacher Teacher Transmission 

2 a Teacher Teacher Transmission 

 b Shared Teacher Construction 

 c Shared Shared Construction 

3 a Teacher Teacher Transmission 

 b Teacher Teacher Construction 

 c Teacher Teacher Transmission 
 
Operation of the IWB 
During the introduction to the exercise on the IWB in episode 1a, the teacher operated the board herself. 
The exercise consisted of two versions of twelve words across two columns. Each word was spelt 
correctly in one column and incorrectly in the other. The students had to identify the correct word and 
click on it. For each word pair the teacher asked a student to come to the IWB. If necessary the teacher 
assisted the students in operating the board. In episode 1b the teacher went through the exercises that the 



Australasian Journal of Educational Technology, 2013, 29(4). 

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students were going to do individually in their exercise books. She had scanned these exercises, primarily 
fill-in exercises, from the exercise book and projected them on the IWB. For each exercise the teacher 
filled in at least one outcome on the IWB.  
 
In lesson 2 the students first responded to two texts that the teacher projected on the IWB (2a). The 
teacher then asked one student to navigate a webpage on the IWB to show how he would look for certain 
information on that page (2b). In episode 2c this student and some other students typed the information 
they had found in their own words in a Word document displayed on the IWB. The teacher concluded this 
lesson by typing a final sentence, with input from the students.  
 
In lesson 3 the teacher operated the board herself throughout the whole lesson. The intensity with which 
the IWB was used was relatively low, as the teacher only used it to project the digital version of the card 
that she was discussing with the class and to point at the text and symbols shown on the card when 
referring to them. During the second episode (3b) the IWB was not referred to, although the teacher did 
ensure that the task card remained on the screen when it went into stand-by mode after a while. 
 
Content on the IWB 
The teacher mainly determined the content on the IWB in all three lessons at the traditional schools. In 
lesson 1 the teacher selected and prepared the exercises that she and the students did on the IWB. The 
exercises have a closed character, with only one correct answer. In episodes 2a and 2b of lesson 2 the 
content on the IWB consisted of two similar texts about castles, written by the teacher, and a preselected 
page from a website. The teacher prepared all of the content in these two episodes. In episode 2c the 
assignment in which students wrote the information they had found in their own words was more open-
ended, thus giving the students more control of the content. Within the context of the preselected 
webpage they could decide which information they found most important and use their own words to 
reformulate this information. In lesson 3 the content on the IWB only comprised the task card that was 
discussed, giving the students no control of the content at all. In episode 3b the teacher did not write 
students' answers on the IWB. 
 
Dialogue 
The dialogues in most of the episodes at the traditional schools consisted of knowledge transmission by 
the teacher and prompting of student recitation. In lesson 1 the teacher checked how well the students had 
memorised and understood the linguistic rules learnt in a previous lesson. She only asked for 
conventional answers, testing the students' ability to give the conventional explanations of grammatical 
terms (example 1.1) and to apply the rules they had learned in the exercises (example 1.2). 
 
Example 1.1  
The IWB shows two columns of words with the names of two spelling rules at the top. There is a grey bar 
above the names of the rules. 
 
Teacher […] I would like to hear it once more.  
 Who can tell me what the acorn rule is. Do I see all hands go 

up? Almost. 
 

 Vincent.  
Student  After a long sound, one consonant.  
Teacher  You know it. Clicks on the grey bar on 

the board. The rule appears 
 Now I wonder… Wow. Long sound, one consonant.   
 
Example 1.2 
The same two columns are on the IWB. After explaining the exercise to the students the teacher asks one 
of them to do the first word. 
 
Teacher Do we get it?  
 Okay, David, can you read the next two words out loud?  
Student  Ontdeking [discovery, misspelled] 

Ontdekking [discovery, spelled correctly] 
Teacher points at the 
words, following the 
student's reading pace  



Australasian Journal of Educational Technology, 2013, 29(4). 

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Teacher Well, show us what you think.  
Student [goes up to the board, teacher hands him the digital pen] Clicks on one of the 

words; "correct" appears 
Teacher Yes, it's correct.  
 Fantastic, David.  
 
In the first episode of lesson 2, in which the students had to identify the differences between the two texts 
on the IWB, the teacher asked the students seemingly open questions. Yet as the lesson unfolded it 
became clear that she was looking for one specific answer, namely that the main difference was that 
difficult words, i.e., academic language, were used in one of the texts, while the other text was written in 
words that students would use themselves, i.e., language appropriate for this age group (example 1.3).  
 
Example 1.3 
The teacher first projects a short text about castles on the IWB, written by herself in academic language. 
She asks the students to read it for themselves and to say what they think of it and why. The students 
mention the use of difficult words and the teacher keeps asking for other criteria. She then projects a 
second text about the same subject, also written by herself but in more accessible language. Again she 
asks the students for their opinion. 
 
Teacher Aidan.  
Student  [inaudible]  
Teacher  You also see a difficult word. Yes, that's a difficult word too.  
 Is there another reason why you think this text isn't so good, 

besides having difficult words? 
 

  Clicks on the board to 
open next text 

 Janet.  
Student  Well, I think this one is good, because here they explain 

more. For example, what's an entrance, well, that's a thing for 
… it's a castle's door. 

 

Teacher Almost right.  Points at board, where it 
says "opening" instead of 
"door" 

Student Yes, opening. And it's written in ordinary words.  
Teacher [points at student] I think it's great that you say that, in 

ordinary words, yes.  
 

 
In episodes 2b and 2c the teacher's questions became more genuinely open-ended and more focused on 
students' own explanations and thus on knowledge construction by the students. In episode 2b the teacher 
asked the student at the IWB to show how he would look for specific information on the webpage 
(example 1.4). 
 
Example 1.4 
The teacher has opened a webpage about castles on the IWB. She asks a student how he would search the 
page for information on how a castle is built and asks him come to the board to demonstrate his search 
strategy. 
 
Teacher Who can tell us, say we're going to do this in a minute, on the 

computer, what do I start with? What am I going to do first? 
 

Student Look for information […]  
Teacher Yes, I have that here. Tell me what I should do then. 

[Reading from the board:] How is a castle built? 
Opens web page 

Student Then you read everything that it says, and then…  
Teacher Am I going to read everything?   
Student No…  
Teacher  So from top to bottom I'm going to read all this. Scrolls down to end of 

page and back up 
Student No, then you look for the chapter how is a castle built?  



Australasian Journal of Educational Technology, 2013, 29(4). 

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Teacher Right. Can you look that up for us?  
 […] Get a chair. Hands student the digital 

pen  
Student  Starts scrolling down 

through the text; looks at 
the text as it goes up the 
screen 

Teacher What are you looking for now? What are you looking at?  
Student How a castle is built, at the chapter titles.  
Teacher [taking a step towards the board] Right. So you look at the 

red letters, at the titles, whether you can find a title about 
building a castle. Very good. 

 

 
In episode 2c the teacher asked the student at the IWB to write the information he had found in his own 
words. Two other students were also asked to write a sentence. Because the students' texts immediately 
appeared on the IWB as they typed, the whole class could closely follow the writing process. Both the 
class and the teacher commented on what the students were writing as they typed (example 1.5). Students 
dictated the final sentence while the teacher typed it. 
 
Example 1.5 
The teacher asks some students to reformulate the information found in their own words and write a 
sentence on the IWB, using a keyboard in the middle of the classroom connected to the IWB. 
 
Teacher What are you going to type?  
Student That below the ground there are traces of wood.  
Teacher Yes. You can write that down.  
Student   Types, looking at 

keyboard. 
 [Close-up of board shows that the student makes a 

mistake in the text and goes back to correct it]  
 

Teacher  There's a red line underneath it, what does that mean?  
Student   Corrects the mistake. 
Teacher  Right, that's very good.  
Student  Finishes the sentence. 
 
In episodes 3a and 3c the teacher read and explained the text on the task card projected on the IWB out 
loud. In the first episode she also asked some of the students to read part of the text and explain what it 
says (example 1.6). She corrected the students' reading mistakes without comment. The teacher also 
demonstrated what the text and icons on the card mean, for instance, by showing them how they could 
find the right card from the box of task cards..  
 
Example 1.6 
The teacher asks a student to explain two icons on the task card on the IWB. 
 
Teacher Then we see another icon. Points at icon of two 

figures on the card 
 What does that mean? Two people, Simon?  
Student Well, that you have to work together.  
Teacher Oh, so working in pairs.   
 So we are going to work in pairs, as I will explain later.  
 There's a 1. Do we have to do 1 assignment? Points at board 
Student No. Grades 1 and 2 have to do it.   
Teacher Very good.  
 
The next episode (3b) consisted of a whole-class discussion on the outcomes of an assignment in which 
pairs of students discussed different forms of transport with each other. In this whole-class discussion the 
teacher gave little feedback on the students' answers, accepting most answers with a short evaluation 



Australasian Journal of Educational Technology, 2013, 29(4). 

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(example 1.7). She did not write the students' answers on the IWB. Throughout the lesson the IWB only 
functioned as a means of reference. 
 
Example 1.7 
The teacher summarises some of the forms of transport that she has heard the pairs of students discussing 
and then asks students to add to her summary. The task card is still projected on the IWB, but there is no 
interaction with the board in this fragment.  
 
Teacher Now tell me… raise your hand if you know with what other forms of transport you can 

go on vacation. Mary. 
Student  By plane, by car, by bike… 
Teacher Yes. 
 Matthew? 
Student On foot. By camper. By… I don't know what it's called. A thing, like…  
Students [mention vehicles, hard to hear] 
Teacher Aha, a tram.  
 Mustafa. 
Student Boat.  
Teacher Yes, with a boat you can. 
 
Interactivity in the IWB-supported lessons at the innovative schools 
 
Descriptions of the lessons analysed  
For this study three IWB-supported lessons at the two innovative schools were analysed. Again eight 
episodes were distinguished. Lesson 4 consisted of two episodes revolving around a presentation by a pair 
of students, based on a WebQuest they had done about bullying. In episode 4a, which took place just 
before the presentation, the teacher discussed with these two students and the class how the students had 
tackled the assignment. In episode 4b, immediately after the presentation, the teacher commented on one 
of the points that the students made in their presentation. 
 
In lesson 5 the teacher made a mind map on the IWB as an introduction to the new topic of "our house". 
This lesson consisted of two episodes, the second episode starting with the introduction of a new sub-
theme by the teacher. 
 
Lesson 6 also mainly consisted of making a mind map. This lesson counted four whole-class episodes. 
First the teacher discussed with the students the assignment on acquainting themselves with the topic "the 
Caribbean" by looking for information (6a). The teacher then made a mind map of the information that 
the students had found during the assignment (6b) and asked the students to formulate research questions 
based on this mind map. She discussed with the students what criteria a research question has to meet 
(6c). The students then formulated research questions in pairs that were subsequently discussed during a 
whole-class discussion (6d). 
 
Table 3 summarises the contextual characteristics of the lessons at the innovative schools.  
  
Table 3  
Lessons at the innovative schools: Context information 
Lesson School Grade (s) Subject Lesson outline Main content on IWB 
4 
 

B1 2/3/4 Science A presentation of students' 
research results; discussion of 
the process of research and 
making the presentation 

WebQuest, slideshow in 
PowerPoint 

5 B2 4/5/6 Science Exploration of new topic Teacher makes a mind 
map 

6 B2 4/5/6 Science Exploration of new topic and 
formulation of research 
questions by students 

Teacher makes a mind 
map and writes students' 
research questions on 
IWB. 



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Interactivity patterns 
The teacher operated the IWB in seven of the episodes at the innovative schools, while in one episode the 
operation of the IWB was shared. In none of the episodes was the IWB operated only by students. Both 
teacher and students determined the content on the IWB together in seven episodes, while in one episode 
the content was fully determined by the teacher. No whole-class episodes with fully student-controlled 
IWB content were observed. The whole-class dialogue at the innovative schools was exclusively aimed at 
knowledge construction in all eight episodes. Table 4 summarises these findings and they are described in 
more detail below.  
 
Table 4  
Overview of interactivity patterns per aspect at the innovative schools 

Lesson Episode Operation of IWB Control of content on IWB Type of dialogue 

4 a Shared Shared Construction 

 b Teacher Shared Construction 

5 a Teacher Shared Construction 

 b Teacher Shared Construction 

6 a Teacher Teacher Construction 

 b Teacher Shared Construction 

 c Teacher Shared Construction 

 d Teacher Shared Construction 
 
Operation of the IWB 
During episode 4a the teacher and the students who had made the presentation operated the IWB together. 
The teacher operated the IWB in reaction to what the students said. For instance, when the students 
mentioned the WebQuest that led to their presentation the teacher used his laptop computer to open this 
WebQuest on the IWB. During episode 4b the teacher operated the IWB, this time to go back to a slide 
that he wanted to discuss with the students. In lessons 5 and 6 the IWB was only operated by the teachers, 
who wrote the students' contributions on the board. In lesson 5 the teacher decided twice that the page had 
become too full and opened a new mind map. In lesson 6 the teacher used the IWB to project a clock (6a 
and 6c), to make a mind map (6b) and to write students' research questions (6d). 
 
Content on the IWB 
In lesson 4 the content on the board was alternately provided by the students and the teacher.  
The students provided most of the content on the IWB in lessons 5 and 6. In lesson 5 the students 
provided keywords for the mind map that they associated with the topic "our house". In episode 5a the 
teacher divided the mind map into categories, some of which were suggested by students. The teacher 
discussed with the students which category a keyword belonged to. When the page become too full the 
teacher opened a new mind map and entered the students' contributions (5b). 
 
In episode 6a the teacher used the IWB for projecting a clock, indicating the time the students had for this 
assignment. In the next whole-class episode (6b) the teacher used the IWB to write keywords from the 
information students had found. Some of the keywords were formulated by the students, sometimes 
slightly modified by the teacher. In episode 6c the teacher again projected a clock on the IWB for the next 
assignment. After group work on formulating research questions the teacher wrote the students' research 
questions on the board during a whole-class discussion (episode 6d). 
 
Dialogue 
In episode 4a the teacher played an active role, mainly focusing on the process of performing a WebQuest 
and making a presentation. He asked the students who had made the presentation to clarify what they had 
done. The teacher then explained the activities to the youngest students or asked other students to explain. 
He summarised or further clarified students' answers and explanations (example 2.1). In episode 4b the 
teacher discussed a suggestion for further research with the students who presented their research results. 
 



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Example 2.1 
The teacher asks the students who made the presentation to explain how they have found the information 
that they are about to present to the class. 
 
Teacher Okay, so you started with a mind map.  
Students Yes, we started with a mind map… 
Teacher [to the class] Who can tell me why they started with a mind map? Grade 4 students know 

this, I wonder if grade 2 and 3 students also know.  
Student 1 Then they could first learn something and… I can't explain. 
Teacher Who can explain? 
Student 2 Because then you learn more about the topic… 
Teacher That's not completely correct, because you don't look for information to put in the mind 

map.  
 Mickey? 
Student 3 Well, you make the mind map because it has things that you haven't looked up but that you 

already know about bullying and you look up that which you don't know so much about.  
Teacher Okay, well said. 
 So you use a mind map to arrange your thoughts. What do I already know? And you also 

find out what you don't know yet. And that's what you can then research. 
 
Most of the whole-class dialogue in lesson 5 and a considerable amount of lesson 6 (episode 6b) revolved 
around the mind maps on the IWB. In lesson 5 the mind map served the goal of activating students' prior 
knowledge. In episode 6b the students' contributions were based on their internet search assignment at the 
beginning of lesson 6. Both teachers sometimes asked the students to clarify their contributions for the 
mind maps (example 2.2) or how the keyword was spelled before writing it down.  
 
Example 2.2 
In lesson 5 the teacher asks the students to provide keywords for the mind map on the topic "our house". 
 
Teacher Lucas. 
Student 1 Bay window. 
Teacher What is a bay window? 
Student 1 [tries to explain what he means, inaudible] 
Teacher [Repeating the student's response, jokingly] A circle at your house. So you put all your 

chairs in a circle? 
Student 1 [tries to explain with gestures what he means] 
Student 2 Like an annex thing. 
Teacher So a bay window is an annex. It's not exactly the same. An annex isn't necessarily a bay 

window, but a bay window is a kind of annex. 
 
In episode 5a the teacher divided the mind map into categories. She often referred to these categories and 
actively involved the students in using the categories, for example by asking them which category their 
contribution belonged to (example 2.3).  
 
Example 2.3 
In lesson 5 the teacher asks the students to provide keywords for the mind map on the topic our house. 
One of the mind-map categories was 'construction'. 
 
Student Iron.  
Teacher Where do you want me to put that?  
Student Well, there at the construction of the house. Because sometimes they 

have iron beams […]. 
 

Teacher I'll write iron beams. Teacher writes 
iron beams 

 
In episode 6a the teacher explained the assignment on searching for information about the topic "the 
Caribbean" and asked the students where they thought they could find this information. In episode 6c, 
before the students started to formulate research questions, the teacher asked them to sum up criteria for a 



Australasian Journal of Educational Technology, 2013, 29(4). 

 491 

good research question (example 2.4) and she negotiated with them on the amount of time they were 
going to need to formulate good research questions of their own.  
 
Example 2.4 
In lesson 6 the teacher asks the students what criteria a good research question must meet, before starting 
to think of their own research questions. She elaborates on the students' answers. 
 
Student That you know exactly what you want to know. 
Teacher That you know exactly what you want to know. 
 So it should not be a very general question. 
 Judy? 
Student A question that you don't know yourself. 
Teacher  Very good. 
 To which you don't know the answer yet. 
 Because otherwise it's no use. Then you already know it, so you don't want to investigate 

it. 
 
Comparison of interactivity patterns between school types 
 
Tables 2 and 4 show the following interactivity patterns. The most common interactivity pattern at the 
traditional schools consisted of teacher operation of the IWB together with teacher-controlled IWB 
content, and dialogue that focused on knowledge transmission. This pattern was evident in four out of 
eight episodes. Four other patterns were found that showed a more active role of the students, in terms of 
operation of the board (three episodes), IWB content (one episode) and/or dialogue characterised by 
knowledge construction (three episodes).  
 
All eight episodes at the innovative schools showed a focus on knowledge construction. In six episodes 
this was combined with teacher operation of the IWB and shared control of IWB content. In one episode 
both the operation of the IWB and control of IWB content were shared, while in one episode both were 
teacher controlled.  
 
Two patterns were found at both school types, each occurring once. In both the traditional and the 
innovative schools we found one episode in which the teacher operated the IWB and controlled the IWB 
content, while aiming at knowledge construction. The other pattern, also found in one episode in each 
school type, consisted of shared IWB operation and control of IWB content combined with dialogue 
characterised by knowledge construction. Table 5 shows these patterns and their frequencies. 
 
Table 5  
Frequency per interactivity pattern per school type 

Interactivity per aspect Frequency per school type 
Operation 
IWB 

Control IWB 
content 

Dialogue Traditional Innovative 

Teacher Teacher Transmission 4 - 

Teacher Teacher Construction 1 1 

Teacher Shared Transmission - - 

Teacher Shared Construction - 6 

Shared Teacher Transmission 1 - 

Shared Teacher Construction 1 - 

Shared Shared Transmission - - 

Shared Shared Construction 1 1 
 
These differences between the school types might partly be related to student age, since at the traditional 
schools only grades 2 and 3 are represented in the study while at the innovative schools grades 2 through 



Australasian Journal of Educational Technology, 2013, 29(4). 

 492 

6 were included (see Tables 2 and 4). However, the most prominent interactivity pattern found at the 
innovative schools was observed across all grades represented in the study. This reinforces the impression 
that the found differences can be attributed to the schools' educational concepts rather than student age. 
 
Conclusion  
 
In this study we explored what types of classroom interactivity the IWB supported in four schools that 
developed their ICT use in a concept-guided way. Two schools had a traditional educational concept, 
characterised by a mainly textbook-driven curriculum, direct instruction and highly structured exercises. 
The other two schools had an innovative concept, characterised by a more open curriculum, with more 
input from students and a coaching role for teachers. We looked for patterns of interactivity within and 
across these two school types. We analysed the interactivity with the IWB in terms of who operated the 
board and who was in control of the content on the board. We further analysed whether the dialogue 
during the IWB-supported lessons focused on transmission or construction of knowledge.  
 
Based on their educational concepts, one would expect the IWB operation and content at the traditional 
schools to be mainly teacher-controlled and dialogue to be directed at knowledge transmission, while at 
the innovative schools the IWB use could be expected to be mainly student-controlled and dialogue to be 
focused on knowledge construction. Our findings, however, are not that unequivocal. In the lessons at the 
traditional schools the most common interactivity pattern found was teacher operation of the IWB 
together with teacher-controlled IWB content and dialogue that focused on knowledge transmission, as 
could have been anticipated. Yet other patterns, with a more active student role, were found as well. And 
even though the innovative schools' educational concept would suggest an active role for students, 
surprisingly in most episodes the teacher operated the board, while sharing control of IWB content with 
the students. Dialogue was focused on knowledge construction as could have been expected.  
 
These findings firstly indicate that the use of the IWB did indeed occur with distinguishable typical 
patterns of interactivity that varied between these two school types. Secondly, our findings also show that 
the IWB-supported interactivity was not always in line with what could have been expected based on the 
schools' educational concepts. Most conspicuously, in the innovative schools it was mainly the teacher 
who operated the IWB.  
 
One characteristic that all four schools in this study had in common was the fact that the IWB was almost 
exclusively used in whole-class lessons. This confirms the findings from other studies that the IWB 
appears to reinforce whole-class teaching. However, our findings contradict the suggestion by for 
example Moss et al. (2007) that use of the IWB also leads to more transmission-style teaching and that it 
reduces the classroom interactivity to the direct interaction with the IWB. Both the innovative schools and 
the traditional schools in our study provide examples of the IWB being used to support whole-class 
teaching in which students had an active role in controlling the content on the IWB and/or in the dialogue. 
The diversity of interactivity patterns in traditional schools and the occurrence of some innovative 
episodes in these schools, may even indicate that the IWB facilitates a transition to a more active role for 
students in the teaching-learning process. 
  
Distinguishing the aspects operation of the IWB, control of IWB content and dialogue in the analysis of 
interactivity has proven useful in this study; it has provided us with a detailed and nuanced picture of 
what goes on in traditional and innovative schools when the IWB is used. Our findings thus contribute to 
insight into the variety of ways the IWB is and can be used in educational practices. They also underline 
that interactivity of IWB use should not be judged on the basis of who operates the board alone. An active 
role for students in operating the board can go hand in hand with teacher-dominated transmission-style 
teaching. This has clear implications for educational practice. When developing learning arrangements 
with the IWB it is important to be aware of these different aspects of interactivity; this awareness can help 
teachers to make conscious decisions about the type of interactions they intend to invoke.  
 
Notwithstanding the nuances, a relation between the school's educational concept and the IWB-supported 
interactivity in whole-class lessons was found. The situations described in this study can therefore serve 
as examples for educators who want to develop IWB use in a concept-guided way. Our finding that 
teachers do indeed develop IWB-supported lessons with types of interactivity that fit the educational 



Australasian Journal of Educational Technology, 2013, 29(4). 

 493 

concept of their school can furthermore promote realistic expectations with regard to the impact that the 
IWB has on classroom practice in a particular school type.  
 
The fact that the most prominent interactivity patterns within each school type occurred in all grades 
represented in the study suggests that the differences in interactivity patterns found between the school 
types are unlikely to be explained by student age alone. For future research into the relationship between 
educational concepts and patterns of interactivity, however, we suggest a more even distribution of grade 
levels across the school types in order to rule out the possibility that the found patterns are related to 
student age rather than educational concept. A larger sample and a more evenly distributed representation 
of both science and arts lessons would also improve generalizability of these findings and deepen our 
understanding of the patterns and relations that were found.  
 
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Corresponding author: Sandra de Koster, s.de.koster@vu.nl 

Australasian Journal of Educational Technology © 2013. 

Please cite as: de Koster, S., Volman, M., & Kuiper, E. (2013). Interactivity with the interactive 
whiteboard in traditional and innovative primary schools: An exploratory study. Australasian Journal of 
Educational Technology, 29(4), 480-495.