herrington


 

Australian Journal of  
Educational Technology 
1997, 13(2), 127-143. 

 

Multimedia, magic and the way students respond 
to a situated learning environment 

 
Jan Herrington and Ron Oliver 

Edith Cowan University  
 
Interactive multimedia and situated learning 
 
Interactive multimedia is a relatively new educational innovation in 
primary, secondary and tertiary level classrooms. While the educational 
community has enthusiastically embraced its potential, relatively little is 
known about how students learn from multimedia, and the design features 
of the software itself that promote effective learning. This article describes 
results associated with a qualitative study into how students use an 
interactive multimedia program designed according to a situated learning 
model. 
 
Situated learning first came to prominence with the publication of several 
articles in the late 1980s (e.g., Brown, Collins, & Duguid, 1989; Collins, 
Brown, & Newman, 1989). The theory captured educators’ imagination 
with its foundations in the apprenticeship system, and its emphasis on the 
importance of learning within the context of real-world applications. The 
practical application of the theory to the design of interactive multimedia 
was made possible by the definition of nine critical characteristics of a 
situated learning model (Herrington & Oliver, 1995) from the extensive 
literature on the subject. The learning environment used in the study needed 
to: 
 

• Provide an authentic context that reflects the way the knowledge will 
be used in real-life 

• Provide authentic activities 
• Provide access to expert performances and the modelling of 

processes 
• Provide multiple roles and perspectives 
• Support collaborative construction of knowledge 
• Promote reflection to enable abstractions to be formed 



128 Australian Journal of Educational Technology, 1997, 13(2) 

• Promote articulation to enable tacit knowledge to be made explicit 
• Provide coaching and scaffolding at critical times 
• Provide for integrated assessment of learning within the tasks.  

 
Each of these characteristics was operationalised within the design of an 
interactive multimedia learning environment entitled Investigating 
assessment strategies in mathematics classrooms (Herrington, Sparrow, 
Herrington, & Oliver, 1997). Many aspects of the model could not be 
incorporated into software per se, such as opportunities for reflection or 
articulation. However, it was important to ensure that the software did not 
prevent these aspects occurring by restrictive design. The critical guidelines 
for the design of the multimedia software, to enable it to support a situated 
learning environment, were that the program needed to provide: 
 

• a physical environment reflecting the way the knowledge will 
ultimately be used (Brown, et al., 1989; Collins, 1988; Young & 
McNeese, 1993) 

  
• a non-linear design to preserve the complexity of the real-life setting 

(Brown, et al., 1989; Collins, 1988; Young & McNeese, 1993) 
  
• a large number of resources to enable sustained examination from a 

number of different perspectives (Spiro, Vispoel, Schmitz, 
Samarapungavan, & Boeger, 1987; Young & McNeese, 1993; 
Brown, et al., 1989; Collins, 1988). 

 
All of these principles were manifested in the interactive multimedia 
program in the design of the interface, the presentation of the media 
elements and in the means of navigation. The program interface simulates 
the front part of a classroom where students can click on the elements to 
access a variety of resources on 22 different assessment strategies 
appropriate for K-12 mathematics (Figure 1). 
 
The assessment program is designed for novice users of computers: 
computer experience is not a prerequisite for use. Those using the program 
are given a choice of five complex and authentic investigations to complete 
which require sustained examination of the resource, and the production of 
both a written report and a verbal presentation. For example, in one 
investigation, students are given two memos: one from a parent requesting 
that her anxious child be assessed in ways other than pencil-and-paper 
tests; and the other from the Mathematics Coordinator requesting a new 
plan for the assessment of mathematics in the school based on recent 
research and best practice. The program is designed so that students use the 



Herrington and Oliver 129 

 

multimedia resources to research and prepare their plan, which they can 
then present as a report at the next ‘staff meeting’ as well as a written 
proposal to the Principal of the school. 
 

 

Figure 1: The main interface of the assessment program 
 
The research study 
 
The purpose of this study was to investigate patterns of behaviour of 
students immersed in a multimedia situated learning environment using this 
resource. Eight preservice teachers in the second year of their 
undergraduate university course (four groups of two) were videotaped 
using the program over two semester weeks as they completed the 
authentic task. In the third week, the students gave their presentations to the 
class, and shortly after, were interviewed. None of the students in the study 
had significant previous exposure to computers or multimedia programs 
and this did not appear to impede their effective use of the program. 
 
Techniques of qualitative analysis recommended by Miles and Huberman 
(1994), Eisner (1991) and McCracken (1988) were used to analyse the data 
collected from the interviews, the transcripts of observation of their 
program use, and other documentary evidence and notes. The analysis 
involved the three step process proposed by Miles and Huberman: data 



130 Australian Journal of Educational Technology, 1997, 13(2) 

reduction, data display, and conclusion drawing and verification. The 
analysis was done with the assistance of NUDIST (Qualitative Solutions & 
Research, 1993), a computer-based qualitative analysis program. 
 
Outcomes and findings 
 
Any study of learning is well informed by descriptions of the activity and 
behaviour of the learners since this has the capacity to significantly 
influence what is learned and how it might be applied later. From a ‘cross-
case’ analysis of the transcripts of the interviews and students’ talk as they 
used the interactive multimedia program, themes and trends emerged which 
began to illuminate the subject of how students used the interactive 
multimedia program which incorporated the characteristics of a situated 
learning environment. Each of these themes—Technology as magic, 
Interface, Navigation, and Search strategies—is discussed in detail below. 
 
Technology as magic 
 

Arthur C. Clarke (1973) in his book Profiles of the future: An inquiry into 
the limits of the possible, described advanced technology as 
‘indistinguishable from magic’ (p. 39). Others have repeated this theme in 
relation to interactive multimedia where many refer to its ‘magical 
qualities’ (e.g., Morrison, 1994). For example, John Sculley, Chief 
Executive of Apple Computer, Inc., in 1988 described the potential of 
multimedia learning environments: 
 

Teachers and students will command a rich learning environment that, had 
you described it to me when I was at school, would have seemed entirely 
magical ... Imagine a screen that can display in vivid colour the inner 
workings of a cell, the births and deaths of stars, the clashes of armies, and 
the triumphs of art. And then imagine that you have access to all of this and 
more by exerting little more effort than simply asking for it to appear. It 
seems like magic, even today. (Sculley, 1988, p. vii) 

 
The active nature of learning, the multitude of choice and the ease of access 
attributed to interactive multimedia by Sculley, are all mirrored in the 
following comment from one of the students: 
 

Oh I liked it, it was much more interesting than sitting in a classroom 
listening to a lecturer because you choose your own information that you 
want to know,  and you’re actually doing it. And it is easy, like you don’t 
have to look around the library for everything that you want. It was all there 
for you. (Interview with Louise) 
 



Herrington and Oliver 131 

 

The sense of magic and amazement at what the students were able to do 
was also evident. They had not been sufficiently exposed to multimedia to 
lose that sense of wonder and excitement that is to be found in the use of a 
new technology. For example, one student expressed wonderment at the 
capabilities of computers: 
 

It’s just so amazing what computers can do, and how things are done. 
(Interview with Debra) 

 
Another student referred to the program as something children would have 
fun with, expressing his own childlike sense of fun: 
 

It was something different to start off with, not just the boring handout or 
something ... it made a lot of sense and it was good to play around. Sort of 
things ... kids would have fun with. (Interview with Rowan) 

 
The spontaneous amazement and delight of one student was obvious when 
he realised the scope and extent of the multimedia resource as he used the 
program: 
 

Mega! So this is a massive, massive database. (Observation of Carlo using 
multimedia program) 

 
In discussing the positive aspects of the assessment program, students 
frequently mentioned its motivational ability. Generally, they attributed the 
motivational power of the learning environment to four aspects. Firstly, 
many students felt that the fact that they could work at their own pace was 
motivating. They made frequent references to the alternative scenario, such 
as, ‘not just the same old boring thing’, comparing the more restricted 
lecture-based approach to the freedom the assessment program allowed. 
Secondly, several students mentioned the motivating influence of the 
partner working in the small collaborative groups. For example, one student 
mentioned that his partner kept him motivated by keeping him on task. A 
third motivating influence mentioned by one student was the authentic 
assessment of the task, both for its intrinsic interest and the fact that it was 
being graded. Fourthly, many students mentioned the inherent motivation 
of computer-based learning, although this was qualified in many instances. 
For example, one student hinted that the motivating power of a computer 
was in its novelty: 
 

I don’t think you can learn everything on a computer, so I think that was 
why it was most motivating cause we’d never done it before. (Interview 
with Zoe) 

 



132 Australian Journal of Educational Technology, 1997, 13(2) 

Other students were more wholehearted in their endorsement of computer-
based learning, for example, the following comment was typical of these 
positive comments: 
 

I find anything on the computer quite motivating. (Interview with Evie) 
 
The students frequently mentioned the word fun in their descriptions of the 
use of the assessment program, not as they were using the programs, but in 
their reflective responses to the interview questions. One might suspect, 
however that the fun might more usefully described, as it was by a young 
student working on a LEGO/Logo problem, as ‘hard fun’ (Negroponte, 
1995, p. 196). The students made comments such as the following: 
 

It was fun, it was something different. (Interview with Rowan) 
It was a different approach, it was fun. (Interview with Evie) 
It is fun, it’s more fun, it gets you a bit more into it. (Interview with Carlo) 
It was set up in a fun way. (Interview with Debra) 

 
However, this positive response to the motivating magic of the interactive 
multimedia experienced by the students was countered by feelings of 
annoyance in dealing with technical problems, described by Clifford Stoll 
as ‘the computer’s universal ability to generate frustration’ (Stoll, 1995, 
p. 60). Stoll and others (e.g. Cuban, 1996; Postman, 1992; Spillane, 1997; 
Slattery, 1995) have been vocal in pointing out the shortcomings of 
computers in learning environments. They argue that, despite the 
sometimes exaggerated claims made for the potential of computers, 
traditional methods such as print, pencils, paper and the post, are often 
faster, more efficient and more economical than the computer-based 
alternatives. None of the technical problems experienced by the students 
was severe enough to impede their effective use of the resource, but they 
clearly caused annoyance and frustration, and distracted them from the 
task. Some of these annoyances related to the program itself: 
 

If we were watching the video and we found something important, and we 
clicked into the notebook, and then the video wasn’t in any more. Like we 
would pause so we still wanted it to be same position but we’d have to start 
it all again. Yes, so that was a bit annoying. (Interview with Zoe) 

 
Some problems were possibly caused by a computer in the laboratory not 
meeting the minimum requirements specified to run the software. For 
example, some of the video clips were very jerky or did not run while the 
soundtrack continued to play: 
 
 



Herrington and Oliver 133 

 

And the video, you’d hear the voice over but it looked like the video was 
dragging, like not connecting. And on some of them we couldn’t even hear 
the audio. It kept on cutting out. Just little things like that, that was the only 
thing that really made it a bit harder for us. (Interview with Louise) 

 
Other frustrations were caused by the sheer unpredictability of computer 
technology, the myriad of unexplained happenings which conspire to defeat 
the human users, such as system crashes, disappearing desktop icons and 
disks refusing to eject. Apart from the expletives occasionally detected on 
the recordings as students used the program, this kind of frustration was 
summed up by a student in the following comment: 
 

Ours had a few glitches and that was really annoying. And just basically 
computer problems, like our mouse wouldn’t work, and the disk wouldn’t 
save. (Interview with Louise) 

 
In dealing with computer technology, students experienced both the 
motivating, magical wonderment that advanced technology can provide, as 
well as the inevitable frustrations that plague every computer user. It is 
possible that with future use, both will move from the extremities of the 
continuum: with regular use, students will take for granted the capabilities 
of the technology and no longer marvel at the magical qualities of 
multimedia; and computer technology will improve to the point where 
technical problems no longer generate barely-containable frustration. 
 
Interface 
 
The user interface of the interactive multimedia program on assessment 
was designed to reflect the real life context of a classroom. An ecological 
or intuitive interface design (i.e., objects within a context) was favoured 
over a lexical design (i.e., words on buttons) as it was more in keeping with 
the situated learning characteristics upon which the program was modelled. 
Such an interface can quickly become intuitive in its use as there is no need 
for the processing of the labels on buttons to intervene in the action of 
retrieving the information (Hedberg & Harper, 1996; Pejtersen, 1993). 
Negroponte (1995), in his discussion of the ‘secret to interface design’ 
writes: 
 

When you meet somebody for the first time, you may be very conscious of 
their looks, speech and gestures. But quickly, the content of your 
communication dominates, even if it is largely expressed through tone of 
voice or the language of facial expressions. A good computer interface 
should behave similarly. (pp.93-94) 

 



134 Australian Journal of Educational Technology, 1997, 13(2) 

Students responded positively to the interface. They appreciated the 
classroom context, and there was no hint that they felt patronised by 
pictures rather than words. The following comment indicates that this 
student was very aware of the difference between the ecological interface 
employed by the assessment program, and the alternative lexical design: 
 

It was set up in a fun way, like it was a classroom. You had your video 
sitting there, you didn’t just have the word ‘video’ and it didn’t have the 
word ‘filing cabinet’ there. It was all there with pictures and you could 
relate it all. (Interview with Debra) 

 
Another described a similar button-based interface design in the following 
comment, suggesting that he had been exposed to this design before, and 
interestingly, equated it with the traditional method of university teaching 
from the blackboard: 
 

The last thing you want is ... a screen you scroll down, then it gives you the 
heading of whatever subject it is and a description, and maybe it could have 
a ‘Press play’ for the videos. It’s just looking at a boring computer screen. 
You could do that straight off the [black]board. What’s the difference? 
(Interview with Rowan) 

 
Sound effects were used in the program to provide instant feedback to 
students that the choice they had selected had been effected. For example, 
clicking on a filing cabinet drawer gave a squeak as the drawer opened 
before the document ‘in the drawer’ appeared on the full screen. Students 
responded favourably to this feature as well: 
 

One thing I will always remember. I went to open the filing cabinet and it 
squeaked. That was excellent ... the first time I heard it, you know, I nearly 
laughed my head off. (Interview with Rowan) 

 
Students generally found the interface was logical in its layout and very 
easy to use. The students appeared to conceptualise the layout of the 
various resources and their contents very quickly. One student mentioned 
that you always knew where to find things. Another compared the 
simplicity of the ecological interface favourably with the verbal nature of 
the Internet, and that he could just click on what he wanted without having 
to search. 
 
The one feature almost all the students disliked about the program was the 
size of the video picture. All the video clips appeared in the area given to 
the television screen, a space with dimensions of approximately 5cm by 
4cm. The size was limited by technical constraints and the limited memory 
capacity of CD-ROMs, an important consideration when dealing with 



Herrington and Oliver 135 

 

memory-intensive files such as Quicktime video files. Some students 
mentioned that they would have preferred the picture to be much bigger. 
Norman (1993) points out that larger screen size enables viewers to be 
‘captured by the event’ and ‘sensory experience is maximized’ (p. 34). 
 
One interesting trend which emerged from the interviews (and this is 
reflected in the quite considerable literature on ‘designers as learners’, cf. 
Jonassen & Reeves, 1996) was the students’ enthusiasm for suggesting 
what could have been done with the interface. One student, made the point 
that the size of the video screen, while suitable for tertiary students, would 
have to be made bigger for younger children. In so doing he was not 
discussing how he found the program’s interface, but had moved into 
general interface design considerations from the perspective of a potential 
user group. Another student suggested that there should have been an apple 
sitting on the desk. When questioned what the apple might do if it was 
clicked, the student became quite excited about the possibilities: 
 

Say ‘Take a lunch break’. Or when they’d had enough [time working on the 
program], you could have a worm come out. (Interview with Zoe) 

 
Similarly, David felt that the notebook should have been instantly 
accessible at all times, and proposed an interface design which would have 
allowed it: 
 

I actually do think a good idea would have been to split the screen to have 
the notebook one side, and what you are reading or watching on the other. 
So you could just like cut and paste. (Interview with David) 

 
Generally, students adapted very quickly to the layout of the interface, and 
found the resources easy to access and use. 
 
Navigation 
 
The organisation of information and material in multimedia programs can 
vary significantly. At one end of the continuum, material is presented 
sequentially, in a linear fashion, where students’ choice of movement is 
limited to going forward or backward. At the other end of the continuum, 
students have unlimited choice in accessing material (see Figure 2). 
 
Navigation systems are provided in interactive multimedia programs to 
enable the user to move around and investigate the resource. The purpose 
of navigation tools within a multimedia program is to: locate and access 
particular information or instructional nodes, purposefully move between 



136 Australian Journal of Educational Technology, 1997, 13(2) 

related information or instructional nodes, to establish one’s current 
position within the information or instructional base, and to return to 
known reference points (Oliver & Herrington, 1995). 
 

s equenti al referenti al  l i nki ngl i near branchi ng  
 
Figure 2: Continuum of multimedia organisation (Oliver & Herrington, 
1995) 
 
The program used in the study was designed to provide referential linking 
to enable students to readily access any media element or document, 
together with the notebook and the help screen. All elements are accessible 
from the main interface, and all clickable objects lead only to a single 
branch, that is, no submenus appear when objects are clicked. Generally, 
students had very little trouble acquainting themselves with the 
navigational systems provided by the program, and they readily 
accomplished the means to investigate the resources. A typical comment 
was one such as this: 
 

It was just so simple to use because it’s all there ... there’s a clear way to get 
back to it. You don’t feel like you’re getting lost. (Interview with Debra) 

 
The students appreciated the non-linear layout of the program from a 
navigational perspective. The freedom to access material in the order of 
their own choosing was commented on by a number of students. For 
example, this student noted that the program did not force the user to 
complete elements of the program in sequence: 
 



Herrington and Oliver 137 

 

You could go through and do whatever you like. It doesn’t say you have to 
do this bit first, and then that bit. You could go and do whatever. (Interview 
with Debra) 

 
One student compared the navigation of the assessment program to a more 
linear structure he had experienced in another computer-based program: 
 

You can’t get lost in it like some programs, you know if you go into this and 
you go into that, then to that. When you want to go back out it is a bit rough ... 
To go back you have to like go back eighteen pages, and you have to go back 
another five, forward another eighteen pages. (Interview with Carlo) 

 
Some students also commented on the fact that the notebook could be 
accessed from any point in the program and that this complemented the 
non-linear nature of the package. The following comment by a student 
implies that the ease of access of the notebook facilitated his ability to 
reflect as he used the program: 
 

I liked being able to do things at my speed, and I like the notebook, being 
able to flip to the notebook from anywhere, and being able to jot down what 
you’re thinking. (Interview with Glen) 

 
Knowing where to look without the fear of getting lost was obviously an 
important consideration in the students’ use of the program, and the 
relatively straightforward nature of the program was compared to 
information-seeking on the Internet. The comment by this student indicates 
frustration with searching in a labyrinth: 
 

It was very well set out and you didn’t have to go looking for things like 
when you’re ‘netting’, you have to go, ‘Well it might be in here, or here’, 
and you look in there, so it leads to something else and you have to go back 
where you started. (Interview with Glen) 

 
Methods of tracking progress in hypermedia environments have been 
likened to the mythical Theseus who laid a thread to retrace his journey 
through the maze of passages in the Labyrinth of Daedalus (Harnden & 
Stringer, 1993; Stringer, 1992). The students’ comments on the 
navigational ease of the assessment program indicates that no retracing aid 
is needed. The navigational systems in the program provide students with a 
relatively flexible, referential system where any node of information is 
accessible within two clicks of the mouse. One student described the 
simplicity of the navigation process: 
 

It’s just the fact that you can reflect as well, you can go back. And once you 
have seen one video you think ‘What did they say in that one back there?’ 
Click, back up to the top and have a look. And it’s all quick as well. Like 



138 Australian Journal of Educational Technology, 1997, 13(2) 

it’s not a long process where you’ve forgotten what you’re after. It’s still in 
your head. You’re thinking ‘Oh yes, oh yes, fair enough’ and it’s upwards 
and back. You can do it and go back and then go back to your notebook and 
make notes. (Interview with Carlo) 

 
The means of navigation used by the students as they worked with the 
interactive multimedia program on assessment was generally found to be 
comparatively simple and effortless. Students had little difficulty finding 
what they were looking for, and were quickly able to return to the main 
interface without having to follow links through several layers of materials 
with the possibility of not finding their way back. 
 
Search strategies 
 
In order to complete the task, students used navigation strategies to access 
the various media elements and to search through the materials in a 
purposeful manner. An audit trail (Schwier & Misanchuk, 1993) was made 
from data provided on the videotapes to determine the manner in which the 
groups accessed the material. 
 
Search strategies employed by students varied considerably between 
groups. Students could choose to approach the search systematically, or use 
an unstructured path through the program. All the groups approached the 
task systematically opting either to investigate the resource by strategy (the 
assessment strategies written on the whiteboard in the interface) or by 
media element (the video clips or the documents in the filing cabinet). 
 
Interestingly, each group used a different search path to examine the 
materials and purposefully seek information. Three initial steps, however, 
were common to all groups at the beginning of their use of the program. 
Firstly, they used an initial orientation strategy where the students moved 
almost randomly around the resource, clicking here and there, trying out 
elements and determining the scope of the resource. The following 
statement summarises the approach: 
 

Firstly we went through, just picked out things of interest to see what the 
package was about, just to see what it had to offer. We did that with about 
five different ones, made a few notes on it ... But we spent the first five 
minutes on interest, just seeing what it was like, playing around with it to 
see what it could do. (Interview with Rowan) 

 
Secondly, every group of students returned to examine the task they had 
been set, either in the electronic form in the notebook, or the hard copy 
form which they had received as a handout. Students took a few minutes to 



Herrington and Oliver 139 

 

reassess the task in the light of the scope of the resource; and then thirdly, 
each group planned an initial strategy, or first move on how they might 
proceed to begin. For example, Steps 2 and 3 are illustrated in the 
following excerpt: 
 

Debra: So are we going to do one from each category? Is that how you want 
to do it? 

Glen: Not necessarily. Let’s just read the question again. (Look at activity 
for 4 minutes). 

Debra: What does it want us to do? 
Glen: So we have to decide which ones we’re going to use and then look at 

the advantages. It actually just says ‘formally request that you prepare 
a report on alternative approaches to assessment in mathematics to be 
presented to staff. Right it also says to prepare a suggested plan on 
how the school might proceed including benefits and problems for 
parents students and teachers. OK. So what if we put these two 
together so you have checklists with space for writing here. 
(Observation of group using multimedia program) 

 
After these initial steps, however, each group approached the task using 
different search strategies. 
 
Each group agreed upon a different method of searching through the 
assessment strategies and the media elements within each strategy. It was 
thought that the list of strategies on the whiteboard in the main interface 
might prompt students to simply follow the order of strategies and to then 
move systematically through the media elements, through all the filing 
cabinet drawers and all the videos. While this was the approach adopted by 
Group 4, the other groups chose to use the whiteboard listing more flexibly. 
For example, Group 1 chose to read all the documents in the Descriptions 
drawer of the filing cabinet before accessing any other elements. 
 
Such a finding endorses the referential navigation system incorporated 
within the interactive multimedia program, and enables each group using 
the resource to create individual search strategies best suited to the needs of 
their own unique response to the investigation. 
 
Summary and conclusions 
 

The analysis of the transcripts and careful viewing of the videotapes 
suggests that the students used the interactive multimedia program based on 
situated learning very differently to the way they might use some other 
types of computer-based resources, such as computer games and the 
Internet. 
 



140 Australian Journal of Educational Technology, 1997, 13(2) 

Although the students’ experience of interactive multimedia use prior to the 
use of the assessment program was limited, and computer experience was 
not a pre-requisite for use, they were able to freely navigate the resource to 
access the media elements. The students experienced a sense of magic and 
amazement at what they were able to do with the program and many 
expressed an almost childlike sense of fun. However, as well as the positive 
aspects of the program, students also expressed feelings of annoyance in 
dealing with technical problems, which clearly caused frustration and 
distracted them from the task. Nevertheless, none of the technical problems 
was severe enough to impede their productive use of the resource. 
 
Students responded very positively to the ecological or intuitive interface 
design and to the sound effects, which generally provided feedback on the 
selection of an element. They generally found the interface was logical in 
its layout and very easy to use, and several expressed the view that you 
always knew where to find things. The students appreciated the non-linear 
layout of the program and the freedom to access material in the order of 
their own choosing. Several students noted that the notebook could be 
accessed from any point in the program and that this complemented the 
non-linear nature of the package. The ease of access of the notebook also 
facilitated students’ ability to reflect on their learning. 
 
Knowing where to look without the fear of getting lost was identified as a 
vital consideration in using computer-based resources. The referential 
navigation system ensured that any node of information was accessible 
within two clicks of the mouse, and generally students found it to be 
comparatively simple and effortless. They were able to return quickly to the 
main interface without having to follow links through several layers of 
materials with the possibility of not finding their way back. 
 
Search strategies employed by students varied considerably between 
groups, although all the groups approached the task systematically rather 
than randomly, opting either to investigate the resource by strategy or by 
media element. Three initial orienting steps were common to all groups. 
They sought out the scope and depth of the resource by freely sampling 
elements, they re-established the task before them and then decided upon 
an initial search strategy. Each group then used a different search path to 
examine the materials and purposefully seek information. 
 
Students used the program reflectively. They spent a good amount of time 
attending to the content of the program, but unlike traditional university 
instruction, proportionally more time was spent reflecting and discussing 



Herrington and Oliver 141 

 

issues with their partners, and composing their response. They enjoyed 
using the program and valued the choice and self-control it allowed in their 
learning about assessment. 
 
It is interesting to note that there was a relatively consistent response 
among the students in relation to the program itself and this response was a 
mix of amazement, appreciation and enthusiasm for the power of this 
electronic medium as a support for learning. But at the same time there 
were many differences observed in the ways in which the students used the 
multimedia package and these diferences all had the prospect to influence 
the learning outcomes achieved. 
 
These findings suggest that the use of the situated learning model can be a 
successful design strategy for interactive multimedia programs. They also 
serve to remind us that in instances where learners are empowered and are 
enabled to assume higher degrees of responsibility for their activity and 
conduct in a learning setting, we need to be cognisant of the various design 
factors which can impede or enhance learning. In multimedia 
environments, these include such elements as the motivational aspects of 
the environment, the interface design, and the navigation elements 
employed. As well as research which explores learning outcomes achieved 
through various design models, it is also important to practice research 
which explores the impact of the more tangible aspects of multimedia 
design such as those explored in this study. 
 
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Collins, A. (1988). Cognitive apprenticeship and instructional technology 
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Collins, A., Brown, J.S., & Newman, S.E. (1989). Cognitive apprenticeship: 
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Cuban, L. (1996, 27 October). Computers in the classroom: Revolutions that 
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