ASSISTING LEARNER’S IN MONITORING THEIR

CONCEPTUAL DEVELOPMENT

On the Design of a Computer-based Service to Support Conceptual Development

Adriana J. Berlanga, Howard Spoelstra, Kamakshi Rajagopal

Centre for Learning Sciences and Technologies (CELSTEC), Open University of The Netherlands, Netherlands

Alisdair Smithies, Isobel Braidman

Medical School, University of Manchester, U.K.

Fridolin Wild

Open University, Milton Keynes, U.K.

Keywords: Conceptual Development, Design, Service, Latent Semantic Analysis, Computer-based Service.

Abstract: This paper elaborates on the design of a computer-based service that supports conceptual development. Our

ambition is provide learners a way to compare their conceptual development against different reference

models, so they recognize the limits of their expertise. These models are (semi) automatically generated

from learning materials and learner text inputs using Latent Semantic Analysis, a technique that identifies in

input text materials the concepts and their relations. The paper explains the envisioned service presenting a

scenario that illustrates how it could be used in formal and informal learning context. After, the paper

elaborates the theoretical background behind the design of the service and, finally, it draws conclusions and

outlines future work.

1 INTRODUCTION

Modern educational approaches stress the

importance of activities such as problem based

learning, joint presentations, discussions,

collaborative knowledge co-construction and so on.

These activities often are assessed on the joint

group‘s performance, instead of on the individual

learner‘s performance. This makes it difficult for

individual learners to recognise their personal

understanding and knowledge of the topic of study.

For that, learners need to receive formative feedback

to identify the boundaries of their knowledge. Tutors

will no always be able to provide that feedback due

to workload. On the other hand, tutors require

reliable means of analysing the progress of learners

in order to provide appropriate guidance and

feedback to each individual. A means of providing

learners and tutors with a clear understanding of the

group‘ and the individual learners‘ conceptual

development, which is also economical with tutor‘s

time, is therefore required.

This paper presents the design of a computer-

based service aimed at supporting learners‘

conceptual development. The service is envisaged to

communicate information to learners intended to

engender the formation of an accurate, (targeted)

conceptualization of a particular topic. The

information should also allow learners to improve

their understanding of a topic without the immediate

need for a tutor. The design of the service is

theoretically grounded in research on expertise

development, a knowledge building process that

comprises both cognitive and social approaches.

The service is envisaged to process learner‘s

textual inputs (i.e., knowledge evidences) and to

return a graphical representation that reflects how a

learner conceptualizes a topic in terms of concepts

and their relations. Learners can then compare their

topic representations against a group reference

model, and/or a pre-defined reference model. The

294

Berlanga A., Spoelstra H., Rajagopal K., Smithies A., Braidman I. and Wild F. (2010).

ASSISTING LEARNER’S IN MONITORING THEIR CONCEPTUAL DEVELOPMENT - On the Design of a Computer-based Service to Support

Conceptual Development.

In Proceedings of the 2nd International Conference on Computer Supported Education, pages 294-299

 SciTePress

group reference model is a representation of how

peers conceptualize the topic, while the ―pre-defined

reference model‖ is a representation of how in

learning materials (or tutor notes) the topic is

conceptualized.

The service explained in this paper goes beyond

existing approaches on measuring conceptual

development (Clariana & Wallace, 2007; Jeong,

2008; Shute, 2008) as we attempt to derive the

reference models and topic representations

(semi)automatically. To this end Latent Semantic

Analysis (Landauer et al., 2007) will be explored in

order to analyze (raw) text and extracting terms and

relationships with respect to their relatedness in

meaning, thereby enabling the generation of

conceptualisation models. Afterwards, these models

will be contrasted to obtain meaningful information

on conceptual development.

The rest of this paper is structured as follows.

First it presents a scenario to elucidate further the

need to monitor one‘s conceptual development and

outlines how the proposed service will work, which

is illustrated with a working prototype of the service.

Next, the paper presents the theoretical

underpinnings for the design of the service. Finally,

it discusses related work and indicates opportunities

for future work.

2 SCENARIO

Marion is a Medical Student in her third year of

study. This week she is working together with a

group of peers on a problem based case about

―cervical dysplasia‖. They have to collect related

information, and discuss and agree on the diagnosis

on the case. At the end of the activity, they have to

present their results to their peers. Learners are also

asked to keep a learning diary in the shape of a blog

to reflect on their learning. The learning activity

goes well, but Marion is not sure that she grasps all

the notions and concepts of the topic, and if her

understanding of the topic corresponds to the level

she is supposed to have reached at this point in her

learning career.

She then decides to use the conceptual

development monitoring service, which is a freely

available widget that can be included in her Personal

Learning Environment. Marion finds the topic space

―Oncology- 3

year‖, created before by her tutor Dr.

Moon. She then submits the blog entry she wrote

about cervical cancer.

After processing Marion‘s blog entry, the service

displays a topic representation graph that includes

the concepts the blog entry contains and how these

concepts are related. The graph uses colours to

identify also different themes (i.e., clusters of

concepts). Figure 1 shows an example of a

representation graph. There Marion can see that in

her blog entry she is relating, for instance, the

concept of ―Cancer‖ with ―Prostate‖ and ―Breast‖.

But also that she relates the theme ‗Cancer‖ to the

theme ―Research‖.

Figure 1: Example topic representation graph.

Marion can also compare her topic representation

graph with other topic representation graphs. These

representations can be, for instance, a group

reference model (a graph that consists of all topic

representations of her peers) or a predefined

reference model, which represents the intended

learning outcomes (a topic representation her tutor

created using learning materials). For instance,

Figure 2 shows the graph Marion sees when she

compares her topic representation (in blue) with the

tutor‘s intended outcomes of the case about ―cervical

dysplasia‖ she was studying with her peers (in

green). There it becomes evident to her that in her

blog she is not mentioning topics related to cancer,

such as the ―Care‖ aspect (showed in the left top

corner of the graph) and the ―Keeping up to date‖

aspect (shown as ‗knowledge‘ in the middle of the

graph).

If Marion decides to ask Dr. Moon for feedback,

she will make her topic representation public, so Dr.

Moon can see it and provide feedback. If this is the

case, Dr. Moon might explain to her that she should

be more aware of the ―Care‖ aspect, which includes

―Diet‖, but also ―Cancer pharmacology‘. She

recommends Marion to read a book chapter as well

as two journal articles so Marion improves her

understanding.

Marion can also use the service to compare her topic

representation graph to that of any particular peer (of

ASSISTING LEARNER'S IN MONITORING THEIR CONCEPTUAL DEVELOPMENT - On the Design of a

Computer-based Service to Support Conceptual Development

295

the peers that have also made their representations

public). The service also keeps a record of Marion‘s

topic representation graphs, so she can compare her

representation graphs over time. This allows her to

gain insight into her progress in understanding the

topic. Figure 3 shows how Marion uses her topic

representation graphs. In this view she can make

graphs public and select which graphs she would

like to compare.

Figure 2: Example comparison topic representation vs.

predefined reference model.

Figure 3: View of topic representations.

Marion likes the service, so she decides to

introduce it in an informal learning context as well:

the Latin American literature group she is part of. In

this context she acts as tutor (―initiator‖) and creates

a topic space for ―magical realism‖. Her friends

include the service in their Personal Learning

Environments, join the topic space Marion created,

and use the service to submit their knowledge

evidences. Some of them submit a blog entry, while

others decide to submit an essay they wrote about

the topic. They work with the service to get topic

personal representation graphs of their

understanding side by side with their friend‘s

representation graphs of the topic. As the service can

create a topic representation graph that is based on

all their joint submissions, they can, when they meet

face-to-face, use that representation (the group

reference model) to see and discuss their shared

representation graph of the topic. They also have

been using well-known literature about the topic to

create a pre-defined reference model. This allows

them to compare and discuss about the differences

and similarities between the different models,

namely their personal topic reference models, the

group reference model, and the predefined reference

model.

3 THEORETICAL

BACKGROUND

The design of the service described above is

underpinned by the idea that learners develop their

expertise taking part in a knowledge building cycle,

which comprises cognitive and social processes.

Research on expertise has shown differences in

the knowledge base development between novice to

expert (Boshuizen & Schmidt, 1992). Experts and

novices differ in their knowledge usage, information

processing, and on how their knowledge structures

are organized (Arts et al., 2006). Findings in Law

(Nievelstein et al., 2008), Physics (Dufresne et al.,

1992), Management (Arts et al., 2006), and

Medicine (van de Wiel et al., 2000) have shown that

knowledge, with increasing expertise, is more

hierarchically structured than novices‘ knowledge,

which appears to be highly fragmented with

concepts loosely connected.

Learners develop their expertise taking part in a

knowledge building cycle, which comprises

cognitive and social processes. The cognitive

process focuses on perception, memory and

meaning; it assumes the memory is an active

processor of information, and knowledge, as a

commodity plays an important role in learning. The

social process assumes that learning is a social

activity that occurs in interaction with others. This

process takes into account both the learner and the

environment, where learners are pro-active

producers of the environment in which they operate.

Consequently, the service is designed to assist

learners in the development of their expertise from

both a cognitive and social perspective. It provides

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learners with diverse ways of comparing their

understanding against different models, mainly

(Berlanga et al., 2009a):

(1) Predefined reference model, considering

indented learning outcomes described in, for

instance, course material, tutor notes, relevant

papers.

(2) Group reference model, considering the

concepts and the relations a group of people

(e.g., peers, participants, co-workers, etc.) used

the most.

The result is that, from a cognitive point of view,

the service provides learners with information that

contrasts their understanding of the topic against the

intended learning outcomes. From a social point of

view, the service provides information to learners so

they recognize the differences in how they

conceptualize a topic with respect to how others do.

Furthermore the service provides cultural and

cognitive artifacts to support the knowledge building

process. In this respect we base our work on Stahl‘s

knowledge building cycle (Stahl, 2006). Following a

social epistemological perspective (Brown &

Duguid, 1991; Lave & Wenger, 1991), Stahl models

the learning process as a mutual construction of the

individual and the social knowledge building. In his

view knowledge is a socially mediated product.

Individuals generate personal beliefs from their own

perspectives, but they do so on the basis of socio-

cultural knowledge, shared language and external

representations. These beliefs become knowledge

through social interaction, communication,

discussion, clarification and negotiation. Learners,

therefore, build knowledge both personally and

collaboratively.

Figure 4: Cycle of knowledge building (Stahl, 2006).

Figure 4 shows Stahl's cycle of knowledge

building. The diagram depicts how the personal and

the collaborative knowing building cycles interact.

The lower left corner shows the cycle of personal

understanding, which might start with a tacit pre-

understanding influenced by personal knowing. This

understanding may change if we explicate the

implications of that understanding and resolve

conflicts or fill gaps—by reinterpreting our meaning

structures—to arrive at a new comprehension. This

typically involves some feedback from e.g., our

experience with artifacts such as our tools and

symbolic representations. New comprehension

gradually settles in to become our new tacit

understanding and provides the starting point for

future understanding and further learning. If we

cannot resolve the problematic character of our

personal understanding alone, which happens mostly

when it is provoked by other people, then we need to

enter into an explicitly social process and create new

meaning collaboratively. To do this, we typically

articulate our initial belief in words and express

ourselves in public statements, and we enter into the

cycle of social knowledge building.

The right part of the diagram depicts how the

social process of interaction with people and with

our shared culture influences the individual‘s

understanding. This process is an interchange of

arguments that provides rationales for different

points of view, which eventually may converge on a

shared understanding.

Our service aims at supporting both knowledge

building cycles. On the left hand side of the cycle, it

provides a cognitive artifact (i.e., a graph

representing learner‘s topic representation) that can

help learners to understand and resolve conflicts or

fill in gaps in their knowledge. If this is not possible,

learners enter into the cycle of social knowledge

building. In this cycle, the service provides a

‗cultural artifact‘ (i.e. a graph that contains the

intended learning outcomes or a single graph that is

based on all peers graphs) that can help to foster

understanding.

Regarding how the service can be deployed in an

educational context, if a cognitive or a social

perspective should be followed, it is important to

stress that many educational practices start by

providing learners with explicit knowledge, and only

after learners have gathered what is considered a

critical mass of that knowledge, they allow learners

to acquire implicit, experiential, applied knowledge.

Likewise, to develop stimulating and suitable

instructional strategies, the instructional approach

needs to take into account whether learners are

novice or experts,. Researchers on instructional

design (Ertmer & Newby, 1993; Jonassen et al.,

1993) do not advocate a single theory of learning,

but emphasise that the instructional strategy and the

content addressed depend on the learner‘s expertise

level. They claim, therefore, that behavioural

ASSISTING LEARNER'S IN MONITORING THEIR CONCEPTUAL DEVELOPMENT - On the Design of a

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strategies can facilitate mastery of the content of a

profession (knowing what); that cognitive strategies

are useful for acquiring procedural knowledge

(knowing how); and that constructivist strategies are

appropriate when dealing with ill-defined problems,

as summarized in Figure 5.

Figure 5: The Continuum of Knowledge Acquisition

Model (Jonassen et al., 1993).

4 CONCLUSIONS AND FUTURE

WORK

In this paper we introduced a computer-based

service aiming to help learners to monitor their

conceptual development. Our ambition is to

implement a service that processes –using Latent

Semantic Analysis– learners‘ learning evidences and

learning materials in order to identify concepts and

their relations to generate different reference models,

which then can be compared. We have elaborated on

a use case that explains how the service will work,

and we have explained the theoretical foundations

behind the design of the service. Particularly, we

discussed how the design of the service is grounded

in findings in the expertise development area and on

a knowledge building model. We also elaborated on

how the service can be used in educational contexts.

It is important to stress that a lifelong learning

perspective was also considered on the design of the

service. That is to say the service is designed in a

way that can be used only for personal use, or in

formal or informal learning situations. A personal

use of the service, learners will not share their

representations, but still will get information on how

they conceptualize a topic, create reference models,

and compare them. In a formal learning context,

tutors can create reference models and the service

can provide information to both tutors and learners.

In informal learning situations, the service can be

used by a group of people, not guided by a tutor, to

share their knowledge and reach a common

understanding.

Up to now, existing tools and software that

identify and approximate learner‘s conceptual

development have been explored, and a proof-of-

concept has been conducted to demonstrate the

generation of reference models (Berlanga et al.,

2009b).

Undoubtedly, more research is needed to

establish how learners would benefit the most from

comparing their conceptual development with the

proposed models (pre-defined reference model or

group model): whether it is good strategy for

learners to see comparisons with both models or,

whether, depending on their level of expertise,

comparisons with different models will be made

available. The type of reference model used may

depend on the level of learner development. The

group reference model, which is based on concepts

and their interrelationships, generated by peers,

would most likely be of use for an individual learner

at a novice level, as at this stage it would correspond

to his/her Zone of Proximal Development

(Vygotsky, 1978). As expertise develops, the group

reference models may still be appropriate, depending

on the development stage of the group as a whole,

but pre-defined reference models may be more

suitable to more advanced learners.

To ensure quality and applicability of our

service, we use a scenario-based design

methodology (Hensgens et al., 2009) which requires

conceptual validation with stakeholders and

formative evaluation of the service. To this end a

validation with stakeholders from the Medical

School, Manchester University will be conducted.

The feedback received will be adopted to design the

first version of the service. This version will be then

evaluated, using primarily qualitative methods, and

the results will be considered to develop a new

release of the service.

ACKNOWLEDGEMENTS

The work presented in this paper was carried out as

part of the LTfLL project, which is funded by the

European Commission (IST-2007-212578).

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