gordon


 

 
Australian Journal of  
Educational Technology 
 
Tracks for learning: Metacognition and learning 
technologies 
 

Julie Gordon 
University of Wollongong 

 
Research into metacognition suggests that learners need to become aware of 
the processes of their learning as distinct from the content of learning to 
improve their learning outcomes. Information technologists have the 
opportunity to take theoretical views of learning and develop design 
models to investigate and demonstrate these theoretical views. One way of 
doing this is by providing interactive multimedia programs that support 
student centred learning. 
 

"There are too many examples of educational multimedia that fail to 
exploit its capability to offer interactive practice of a subject" 
(Laurillard, 1993). 

 
This paper outlines an investigation into the nature of metacognition and its 
relation to the learning process in a constructivist interactive multimedia 
learning environment. 

 
Learning is an intriguing process for students, teachers and designers of 
educational software The learning and teaching process may now be one 
that is combined and integrated into interactive multimedia programs to 
support the construction of meaning by the learner. Computers provide 
students with access to information and knowledge reconstruction that is 
presented in multiple media. A review by Jonassen (1996) further supports 
this view where he proposes that "multimodal access is essential when 
teaching today's video generation". Students now have the opportunity to 
take advantage of learning by using interactive multimedia programs in 
order to develop problem solving techniques. 
 
One way of supporting the students learning processes and encouraging 
problem solving skills is through the provision of metacognitive support 
for the writing process that can be used by learners whilst solving 
problems within an information landscape. An example of this 
metacognitive support in the form of genre templates has been embedded 
in an interactive multimedia program. The package described gives 
students an opportunity to gather, organise and illustrate their ideas 



Australian Journal of Educational Technology, 1996, 12(1) 47 

dependent on a set task. Within the interactive multimedia program the 
metacognitive support template is unique in that it aids students in their 
thinking, information processing and monitoring of their own learning 
processes. Earlier interactive multimedia programs promoted learning 
environments where students mirrored accepted views. In addition this 
version facilitates an environment where learners interpret their own 
views of reality by understanding how they arrived at these 
interpretations and views. It provides support in the form of new 
schemata in the process of accommodating mental models. 
 
This paper will briefly outline the definitions associated with and the 
relationships between metacognition and learning technologies. It will also 
consider how this relationship effects the learner, teacher and future 
designers of interactive multimedia programs. 
 
Metacognition 
 
Metacognition has been defined as an "awareness of one's own cognitive 
processes rather than the content of those processes together with the use 
of that self awareness in controlling and improving cognitive processes" 
(Biggs & Moore, p 527, 1993). Other researchers have referred to 
metacognition as "cognitive strategies", (Paris and Winograd, 1990) 
"knowledge about executive control systems" (Brown, Harper and 
Hedberg, 1994), "monitoring of cognitive processes" (Flavell, 1976), 
"resources and self regulating learning" (Osman and Hannafin, 1992) and 
"evaluating cognitive states such as self appraisal and self management" 
(Brown, 1996). These are broad terms that are all equally important 
depending on the characteristics of the learner and their approach to 
learning. If we look at learners who are aware of their metacognitive 
processes they will more than likely be people who possess "self 
determination or autonomy in learning and problem solving. They will be 
able to refer to the what, how, when, where and why of learning when 
carrying out complex cognitive activities. 
 
These will be the learners who do this by: 
 
• planning, deciding what their goals are and what  
• strategies to use to get there; decide what further  
• knowledge or resources they need;  
• monitoring progress along the way; am I going in the right direction;  
• evaluating when I have arrived; and  
• terminating when the goals have been met (Biggs and Moore, p307, 1993). 
 
A review of Houssman's (1991) research further supports this notion. On 
investigating metacognitive processes through student self reporting 
journals she found that students who were aware of their metacognitive 
processes and monitored their own learning processes became more 
proficient learners in a computer class as compared to those who did not 



48 Australian Journal of Educational Technology, 1996, 12(1) 

monitor their metacognitive processes. Metacognition for the purpose of 
this review is defined as self awareness of one's own cognitive processes. 
 
Learning technologies 
 
In order to define learning technologies one needs to look at the 
relationship between human learning and those systems techniques and 
equipment which address this fundamentally human attribute. Rieber 
(1991) has examined this relationship in his work on instructional 
technology examines learning from a constructivist perspective based 
upon the work of Piaget's theory of cognitive development. 
 

Learning can be viewed not so much as the acquisition of knowledge but as 
the constant reconstruction of what is already known. Individuals do not 
simply add information to their knowledge banks. They either revise 
existing mental structures to accept new information or formulate new 
structures based on old ones when an existing structure is no longer 
sufficient. Engaging new ideas to prior knowledge in a never ending 
pattern of going from the known to the unknown. Learning within a 
microworld relies on the natural tendency of a learner to seek equilibrium. 
Successful microworlds encourage learning conflicts to arise in order to 
activate the process of equilibration. It is only through the resolution of 
these conflicts that learning can take place (Rieber, 1991). 

 
The computer as a microworld by engaging the learner, acts as an 
interactive medium and allows for the development of the learners 
personal knowledge acquisition and representation by amplifying their 
thinking skills. 
 
"Learning technologies represent any environment or definable set of 
activities that engage learners in knowledge construction and meaning 
making" (Jonassen, 1995). Interactive multimedia programs can be used as 
a means to support student learning and knowledge structures. In line 
with the philosophy of children constructing their own learning through 
interaction with experiences in which they "struggle" to find equilibrium 
between their current level of understanding and that of the next, it could 
be argued that it is not the computer that should provide the knowledge 
structure for the learning process and guide the student through a 
program, it is the student. Students should develop their own 
understanding of the structure of the information. This does not mean a 
simple pass throughout the information base. What it does mean is placing 
students in an environment that supports the way in which they can 
construct their own understanding of a particular knowledge base or piece 
of information. 
 
What a powerful computer software environment provides is the tool for 
"empowering" students to engage in a cognitive struggle with new 
learning situations, allowing them to take control of their own learning, 
reflecting on their thinking and on the consequences of choices they make 



Australian Journal of Educational Technology, 1996, 12(1) 49 

all of which are factors in developing metacognition (Sewell, 1990). 
Additionally, it can provide a context for learning and the opportunity to 
observe "expert" models of particular skills. The author is of the opinion 
that computer software environments should be used as facilitators of 
thinking and knowledge construction so that students can devise their 
own ways of handling the information that is presented in multiple modes 
of representation. 
 
What is the relationship between metacognition  
and learning technologies? 
 
Learners need to know how to monitor and regulate their own learning 
processes when solving problems within an interactive multimedia 
learning context. The author believes that metacognition helps learners 
exhibit cognitive processes that analyse and manage their own thinking in 
pursuit of knowledge acquisition in order to solve problems, gain insight 
and become critical thinkers. An example of a metacognitive tool is a genre 
template. Metacognitive tools in the form of genre templates for writing 
can provide further support for the process of learning. In an interactive 
multimedia student centred learning environment genre templates help 
remind students of planning, monitoring and regulating their own 
learning. If students know how to monitor their cognitive processes and 
regulate their learning to solve problems they will then be better able to 
select appropriate metacognitive strategies to facilitate their own problem 
solving skills. Problem based learning and interactive multimedia can 
support students by encouraging metacognitive learning and problem 
solving skills. 
 
Instructional technology provides us with both metacognitive support 
tools and cognitive tools that are based upon a constructivist 
epistemology. Constructivism is concerned with the process of how we 
construct meaning and knowledge in the world as well as with the results 
of the constructive process. How we construct knowledge depends upon 
what we already know, our previous experiences, how we have organised 
those experiences into knowledge structures such as schema, mental 
models, and the beliefs that we as individuals use to interpret our own 
realities of the objects and events we encounter within the world. 
 
Norman (1983) argues that 
 

computers support reflective thinking when they enable users to compose 
new knowledge by adding new representations, modifying old ones and 
comparing the two. 

 
Cognitive tools should be readily accessible to learners to support 
reflective thinking on what they have learnt and how they came to know 
it, supporting internal negotiation of meaning making and constructing 
personal representations of meaning making within the context of 



50 Australian Journal of Educational Technology, 1996, 12(1) 

learning. "Cognitive tools provide an environment and vehicle that often 
requires learners to think harder about the subject matter domain being 
studied while generating thoughts that would be difficult without the 
tool" (Jonassen, 1996). Jonassen views technology as a tool for accessing 
information, representing ideas, communicating with others and 
generating products. 
 
An example of the relation between metacognition  
and learning technologies 
 
Exploring the Nardoo is an example of an interactive multimedia program 
which provides a range of cognitive tools in an information landscape to 
support student investigations, reflections and thinking processes. 
Simulations and support tools which allow: multimedia reporting are 
embedded in the package and are supported by several metacognitive 
tools for the writing process. These tools not only include details about 
genre but also scaffolding templates to support the learners (Harper, 
Hedberg, Wright and Corderoy, 1996) in constructing their own realities 
using the constructs and processes in the environment on a new content 
domain. 
 
The templates provide a cognitive support for problem solving by 
establishing a frame work for student presentation which will concentrate 
thought, facilitate investigation and the development of critical and 
creative thinking. It incorporates problems that challenge students to 
become active participants in the learning process. The Nardoo provides 
the student with a flexible set of tools, made available through a personal 
digital assistant, for the investigation process. This package also enables 
the user to record thoughts and impressions "on the fly" whilst examining 
media stories. It has the potential to help students reorganise or revise 
their thoughts to better make sense of what they see and hear. Students are 
able to document their emerging ideas in support of an investigation or 
problem solving exercise whilst viewing different media. One way of 
organising thoughts that are presented as information represented in 
multiple media is by using a template. 
 
By making such templates available and encouraging their use, we are 
assisting students through a modelled form of outlining. Identifying 
concepts within their notes that bear some relationship to part of a 
template structure requires high order thinking skills which "a) causes 
focusing on important points, b) helps students gain familiarity with text 
structure, c) aids retention, d) generates useful alternative texts to 
supplement materials read, and e) causes active participation in learning" 
(Biancol and McCormick, 1989 in Schroeder & Kenny, 1994, p966). "The 
value of this modelling process is not faculty, learning style, level of 
school, or type of writing dependent" (Harper, Hedberg, Bickell, Wright 
and Corderoy, 1996). It is to help students match their learning processes 
with that of a genre template. While at the same time organising 



Australian Journal of Educational Technology, 1996, 12(1) 51 

information and the reconstruction of new knowledge at a time 
appropriate to the student. 
 
Students need to cultivate and develop their own understandings and 
interpretations. Of significant importance in this package is the 
development of a "new genre" born of computers and their associated 
technologies the multimedia genre, which is a melding of all 
communications, written, oral visual and aural. How students monitor, 
regulate and control not only their cognitive processes, but the 
information and knowledge structures they wish to present, which is 
represented in multiple media, will be of great assistance to teachers and 
instructional designers. 
 

 
Genre template from Exploring the Nardoo 

 
Who is this for 
 
What research in this area is not showing is how metacognition, as a 
support tool for the writing process, can be manipulated and extended by 
students for themselves in an interactive multimedia program. To further 
enhance meaningful learning within these programs researchers need to 
look at how learners use metacognitive support, in the form of genre 
templates, as processes, strategies and skills, in organising the presentation 
of reconstructed knowledge and information that is put forward in 
multiple modes of media for representation during the formulation of a 
solution to a problem. 
 



52 Australian Journal of Educational Technology, 1996, 12(1) 

More research is needed is this area to help designers provide learning 
environments that give learners access to metacognitive support. Rather 
than developing ever more powerful teaching hardware, researchers 
should be concentrating on how to help learners think more effectively. 
According to Jonassen (1992) we should focus less on developing 
sophisticated multi media delivery technologies and more on thinking 
technologies, those that engage thinking processes in the mind Recent 
research by Jonassen and Lehrer indicates that "learners develop critical 
thinking skills as authors, designers and constructors of knowledge and 
learn more in the process than they do as the recipients of knowledge 
prepackaged in educational communications" (Jonassen, 1996). Learners, 
teachers and instructional designers must all work towards the same goal 
of creating a richer student centred environment that develops learners 
metacognitive abilities and problem solving skills. 
 
Learners perspective 
 
In relation to the software package Exploring the Nardoo, cognitive tools (a 
simulator, presentation guide and genre templates) are aimed at providing 
support on a deeper level for the exploration process. They greatly enrich 
the quality of the problem solving process for students by providing the 
student with unhindered access to act and become immersed in a real 
situated process. They also promote the adoption by the student of the 
active learner mode and in so doing support the active construction of 
knowledge during the process of solving a problem (Harper, Hedberg, 
Wright and Corderoy, 1996). A necessary skill in problem solving is the 
ability to collect and manipulate and analyse many different forms of data 
and then present them in meaningful and useful ways to any of the many 
different discourse communities. The genre template tool in the 
presentation guide provides a suitable mechanism for the support and 
development of this skill. Student support for the collection of this data 
through note taking and the resultant solutions to problems need to 
include modelling of various styles of discourse used in different 
communities. 
 
From a learners perspective, using the genre templates should encourage 
qualities of meaningful learning. Meaningful learning includes: "active, 
constructive, collaborative, intentional, conversational, contextualised and 
reflective learning" (Jonassen, 1995) together with an awareness of this 
process. The use of genre templates helps learners choose strategies in 
planning, monitoring and regulating implied learning by identifying the 
relationship between their work and the appropriate genre. Students can 
devise their own ways of learning or solving problems and in doing so can 
be at times engaging in active, construction, collaboration intentional, 
conversational, contextualised and reflective learning by using interactive 
multimedia programs. Jonassen and Reeves (1996) through their ongoing 
research into learning technologies and the use of authoring environments 



Australian Journal of Educational Technology, 1996, 12(1) 53 

as cognitive tools, found that students needed to develop major thinking 
skills to use as designers of learning (Carver, Lehrer, Connell and 
Erickson, 1992). The author wishes to consider that if students are not 
aware of how to learn they now have the chance to further sharpen their 
metacognitive strategies and abilities by using the metacognitive tools 
provided as support in interactive multimedia information landscapes. 
Alternatively, if they are aware of their metacognitive processes when 
using interactive multimedia they will be able to understand the relevance 
of metacognitive support and perhaps start to use a combination of these 
support tools in ways not yet discovered by teachers and instructional 
designers. Other questions will include whether or not the implementation 
of this support is dependent on learners approach to learning, motivation 
and cognitive style. 
 
In contrast, this cannot occur in traditional education institutions because 
they engage learners in reproduction, reception, repetition, competition 
and prescription. The use of technology however, supports learners in 
knowledge construction; not reproduction, conversation; not reception, 
articulation;, not repetition, collaboration; not competition and reflection; 
not prescription (Jonassen, 1995). At this stage very few interactive 
multimedia programs are designed to support learners as authors or 
designers of their own knowledge reconstruction and learning processes. 
Brown (1996) agrees with the use of technology to support processes of 
learning and recommends that "future research is needed in this area. The 
learning process and the end product should all have equal importance for 
the development of deep, self regulated learning." Interactive multimedia 
programs can support students during the construction process and in 
turn can provide a wonderful cognitive tool for deep self regulated 
learning. Yet interactive multimedia programs are still being developed 
that support and encourage surface approaches to learning. 
 
Designers perspective 
 
Too many software programs are being produced that place the learner in 
active control of processes and interaction but are still only a kind of 
metacognitive drill and practice (Stern, 1992, p230) via information data 
bases. This practice overlooks a basic point that learning is fundamentally 
an edition process and that it is not skills that improve but ideas that 
change. Learning is not a mechanism learnt through repetitive practice but 
referred previously by Jonassen as conversation, articulation, intellectual 
partnering, knowledge construction, collaboration and reflection and as 
Reiber suggests a resolution to conflict resulting from disequilibrium. 
Designers need to be aware of the metacognitive processes that learners 
incorporate into their own learning so as to better design interactive 
multimedia programs that support how learners cognitively process and 
organise information in problem based and student centred learning. 
 



54 Australian Journal of Educational Technology, 1996, 12(1) 

Teachers perspective 
 
According to constructivism, the teachers cannot map their own 
interpretations of the world onto the learner because they do not share a 
set of common experiences and interpretations. Reality (or at least what 
we know and understand of it) resides in the mind of each knower who 
interprets the external world according to his or her own experiences, 
beliefs and knowledge. When using multimedia/hypermedia 
environments as a resource for cognitive processing and problem solving, 
Idol, Jones and Mayer (p80, 1991) provide us with research that is in the 
hallmark of successful models of teaching to emphasise thinking skills. 
These include modelling, coaching, inquiry, articulation, reflection and 
exploration all of which can be found in Exploring the Nardoo in the form of 
support for knowledge construction in the formulation of interpreting a 
solution to a problem. The genre templates support this notion of 
providing strategies that will help students encode and manipulate the 
information they encounter. This helps students develop further 
information and note taking skills. Teachers can at any given point, guide 
students through this process, as the students own realities unfold. 
 
A teacher now has to adapt to the role of being a knowledge transmitter in 
a bid to create students who are flexible, motivated problem solvers. 
Exploring the Nardoo offers teachers the opportunity to individualise 
instruction, place learners in open-ended student centred investigation 
and shift from their traditional instructor role to that of mentor and co 
learner (Harper, Hedberg, Wright and Corderoy 1996). The computer and 
the students use of metacognitive support tools has the potential to change 
not only what teachers teach in terms of subject matter or content but how 
they teach in terms of process. 
 
Conclusion 
 
Several factors need to be addressed in the relationship between 
metacognition and learning technologies. Learners need to be made aware 
of how they learn, by monitoring and gaining control of their cognitive 
processes. One way of doing this is through interactive multimedia 
programs with embedded metacognitive support tools for processes such 
as writing, that promote problem solving skills for the organisation of 
information presented in multiple media for representation. This will 
enable an increased understanding of how students interact with the genre 
templates as a means of support for the writing process during the 
learning process, required both for the teacher, instructional designer. 
Lastly the author feels that systemic change can occur through continued 
research, the integration and implementation of well designed interactive 
multimedia programs based upon theoretical approaches to 
constructivism. 
 



Australian Journal of Educational Technology, 1996, 12(1) 55 

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Please cite as: Gordon, J. (1996). Tracks for learning: Metacognition and 
learning technologies. Australian Journal of Educational Technology, 12(1), 46-
55. http://www.ascilite.org.au/ajet/ajet12/gordon.html