LEARNING STYLES THEORY FOR INTELLIGENT LEARNING

ENVIRONMENTS

Adapting the Instruction

Yasmín Hernández and Guillermo Rodríguez

Gerencia de Tecnologías de la Información, Instituto de Investigaciones Eléctricas, Reforma 113,Cuernavaca, Mexico

Keywords: Learning styles, LMS, Intelligent learning environments, Learning objects.

Abstract: It is well known that personalized tutoring helps to improve the learning process and to obtain better results.

With this aim we are developing a model including the learning styles of the students. We based our model

on the Felder-Silverman Learning Styles Model. According to the student learning style, the instruction is

established by a proposed set of rules. To prove our model we propose to use an LMS in compliance with

SCORM. In this paper we present our general proposal.

1 INTRODUCTION

Up to the present time most of the intelligent

learning environments personalize learning basically

by following what the student knows and selecting

the next learning object or tutorial action according

to the student’s current knowledge. This is usually

implemented with a student model where student’s

knowledge state is a subset of the knowledge of an

expert in the subject matter (overlay model).

However, to adapt the instruction to students is not

only concerned with students’ current knowledge;

therefore many other proposals have appeared to try

to adapt the instruction to other aspects of students.

In (Ferguson et al, 2006) the authors propose to

model students in terms of skills mastery to select

the next problem or hint to be presented to students.

There are proposals which emphasize the

importance of the motivational and affective state.

For example, self-efficacy has been proposed as a

highly accurate predictor of students’ motivational

state and their learning effectiveness (McQuiggan

and Lester, 2006). Other proposals of

personalization are based on the use of affective

models, for instance, a model of a affective tutor is

presented in (Hernandez, Sucar and Conati, 2008);

however few proposals are reported in the literature;

and the same happens with personalization using

learning styles (Graf and Kinshuk, 2007). A general

framework to include learning styles in educational

systems is presented in (Parvez and Blank, 2008). In

this paper we present a proposal to adapt the

instruction base on the Felder-Silverman Learning

Styles Model; the instruction is presented according

a rules set taking into account student learning style

which is identified by an assessment instrument gave

to students. The rest of the paper is organized as

follows: in the next section, the learning styles

model is presented; in section 3, an introduction to

the LMS Moodle is provided; in section 4 we

present our proposal, we justify why to use Moodle

to implement intelligent tutors at Instituto de

Investigaciones Eléctricas (Electrical Research

Institute) in México. Finally, conclusions, future

work and references are provided.

2 LEARNING STYLES MODEL

Learning theories describe proposals about how the

people learn new concepts and abilities; several

learning theories have been proposed, all of them

states different, and some times, contrasting points

of view; for example the dispute between proposals

focused in the student and proposals focused in the

teachers. The learning styles theory relies on the

hypothesis where each individual has a particular

way to learn including strategies and preferences,

emphasizing that individuals perceive and process

information in different ways. Consequently,

learning styles theory states individuals’ learning has

more to do with a process focusing the learning style

456

Hernández Y. and Rodríguez G..

LEARNING STYLES THEORY FOR INTELLIGENT LEARNING ENVIRONMENTS - Adapting the Instruction.

DOI: 10.5220/0003403604560459

In Proceedings of the 3rd International Conference on Computer Supported Education (CSEDU-2011), pages 456-459

ISBN: 978-989-8425-49-2

 2011 SCITEPRESS (Science and Technology Publications, Lda.)

than with the individuals’ intelligence

(Funderstanding, 2008). Several learning styles

models have been proposed, our proposal is based

on the Felder-Silverman learning Styles Model (Graf

and Kinshuk, 2007; Blouin, 2010; Felder and

Silverman, 1988), which is a well-known and

broadly used learning styles model. In this section,

firstly, the model is presented and then the rule-

based proposal to incorporate learning styles in

intelligent tutors is presented.

The Felder-Silverman categorizations of learning

styles are: sensing-intuitive, visual-verbal, active-

reflective, and sequential-global.

 Active and reflective learners. The active style

learner understands information best by doing

something with it and likes group work. The

Reflective style learner understand

information best by thinking about it quietly

first and prefers to work alone.

 Sensing and intuitive learners. The sensing

learner likes learning facts and solves

problems by well-established methods and

dislike complications. The intuitive learner

prefers discovering possibilities and

relationships and likes innovation and dislikes

repetition.

 Visual and verbal learners. The visual

remembers best what they see: pictures,

diagrams, flow charts, time lines, films, and

demonstrations. The verbal gets more out of

words, written and spoken explanations

 Sequential and global learners. The sequential

gains understanding in linear steps and

follows logical stepwise paths in finding

solutions. The global learns in large jumps and

solves complex problems quickly once they

have grasped the big picture.

To identify the learning style of a person, the

Felder-Silverman assessment instrument is used; this

instrument is a Soloman and Felder questionnaire,

consisting of 44 questions (Felder and Soloman,

1993).

To implement the Felder-Silverman Learning

Styles Model we use a collection of rules where each

rule proposes a set of teaching instructions for one

learning style (Savic and Konjovic, 2009). Table 1

shows the rules.

Rules are conceptually easy to implement in

tutoring systems. However, to apply these rules,

every lesson of a course has to be converted into 8

different lessons according to the teaching

instructions. This effort is justified if there are many

potential students classified in each of the learning

styles so that they can benefit of the personalized

learning objects. Given the learning styles remains

over the complete session, the learning style of a

person is assessed once at the beginning of the

course.

Table 1: Rules of teaching instructions for each learning style in the Felder-Silverman model.

Learning style Teaching instructions

Active Show exercises at the beginning of the chapter because they like challenges and problem solving

Show less examples. They are not interested in the way others have done something, because they

want to solve a problem by themselves

Reflective Show exercises at the end of a chapter

Show examples after explanation content, but before exercises

Show less exercises, because they learn better by thinking about a topic instead of solving problems

actively.

Sensing Show examples at the beginning of a chapter (before explanation content) because they like

concrete content.

Show exercises after explanation content, because they solve problems by already learned

approaches

Intuitive Show less examples, because they like to discover topic application by themselves

Show examples after explanation content, because they like abstract content more than concrete

Show exercises before explanation content, because they like challenges

Show less exercises with a similar teaching goal because they don’t like repetition

Visual If possible, show resources as a picture or a video

Verbal Show resources as a text or an audio

Sequential Show learning content in a standard sequence – explanation content, examples, exercises and

summary, because they like linear approach

Global They are less interested in details, because they need to create a global picture of the topic.

Therefore, add an overview of each chapter at the beginning of the lesson

Show summary before examples and exercises, because summary helps you to create a global

picture

LEARNING STYLES THEORY FOR INTELLIGENT LEARNING ENVIRONMENTS - Adapting the Instruction

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3 LEARNING MANAGEMENT

SYSTEM

The use of programs to manage the activities around

training and education is rapidly growing;

universities and other institutions are widely using

them to support the education/training programs.

The simplest definition of learning management

system (LMS) is a software application for the

administration, documentation, tracking, and

reporting of training/education programs for e-

learning and b-learning; however, an LMS is also

concerned with centralize and automate

administration, provide self-service and self-guided

services, assemble and deliver learning content

rapidly, consolidate training initiatives on a scalable

web-based platform, support portability and

standards and personalize content and enable

knowledge reuse (Ellis, 2009). The functions of an

LMS vary from systems for managing training and

educational records, to software for distributing

courses over the WWW with features for online

collaboration.

An LMS should provide the following elements:

The syllabus for the course, administrative

information, a notice board for up-to-date course

information, student registration and tracking

facilities, basic teaching materials (These may be the

complete content of the course, or copies of visual

aids used in lectures), additional resources

(including reading materials, and links to outside

resources in libraries and on the Internet), self-

assessment quizzes which can be scored

automatically, formal assessment procedures,

electronic communication support including e-mail,

threaded discussions and a chat room, with or

without a moderator, differential access rights for

instructors and students, production of

documentation and statistics on the course, easy

authoring tools for creating the necessary documents

including the insertion of hyperlinks. In addition, the

LMS should be capable of supporting numerous

courses, so that students and instructors in a given

institution experience a consistent interface when

moving from one course to another (Wikipedia,

2010). An important feature of LMS is the

adherence to standards, such as SCORM (Ellis,

2009); it means that the LMS can share content

complying with standards regardless of the

authoring system that produced it.

There are many commercial and open source

LMS. Some of popular commercial LMS are:

Blackboard (Blackboard, 2010), WebCT (WebCT,

2010) and the leading open source LMS is Moodle

(Moodle, 2010). For our proposal we decided to use

Moodle.

Moodle is a software package for producing

Internet-based courses and web sites. It is a global

development project designed to support a social

constructionist framework of education. The word

Moodle was originally an acronym for Modular

Object-Oriented Dynamic Learning Environment.

Moodle allows providing documents, graded

assignments, quizzes, discussion forums, etc. to

students with an easy to learn and use interface.

Figure 1 shows a screenshot of the Moodle site we

are assembling to develop our proposal for the

Instituto de Investigaciones Eléctricas (Electrical

Research Institute) at México.

Figure 1: Moodle site for the Instituto de Investigaciones

Eléctricas (Electrical Research Institute) at México.

Figure 1 shows the elements from a Moodle site

we are developing for the proposal; it is composed

by a log-in section, a calendar, a news section and a

list of the available courses. The availability of a

course depends on the student profile.

As we mentioned, an important feature of LMS

is the adherence to standards, such as SCORM,

therefore, we develop the instructional material as

lessons, tests, and exams in compliance with

SCORM (ADL, 2009). SCORM is a specification

for e-learning system.

To develop courses to be presented by Moodle

and SCORM compliant we base our proposal on an

algorithm rooted in artificial intelligent planning

techniques proposed by (Brusilovsky and Vassileva,

2003). This method obtains a SCORM activity tree

from a AND/OR graph or a tree that represents a

tutor plan. In this way, an individual course is

generated for each student base on her individuals

needs and on a learning goal. This will allow

running SCORM compliant intelligent tutors in

Moodle.

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4 INTEGRATION APPROACH

As previous work, we developed a student model

that considers the affect and knowledge to decide the

next tutorial action. The tutor monitors the affective

state of students and reacts in consequence. The

affective state is established with base on students’

personality traits and their performance in the

tutorial session (Hernández, Sucar and Conati, 2009;

Hernández, Sucar and Conati, 2008). Now, we want

to have more adaptive instruction identifying the

learning style of students and to provide students

with an instruction according with their learning

style. In this way, our integration approach allows

building intelligent tutors that are adaptive in

response to the knowledge state, the affective state

and the learning style of the students. To incorporate

learning styles in the adaptation of tutoring systems

allows identifying the best tutorial action given the

students’ preferences, strategies, experience, and so

on.

The learning style assessment instrument

(Felder-Silverman) is applied to the student to

indentify the student learning style just once, when

the student visit for the first time the educational

environment or maybe at the beginning of a course.

Once, the learning style is identified we base in the

AND/OR graph and in the rules from Table 1, we

generate a course individualized for each student. In

this way, the learning style determines the type of

explanations to be presented to the student when

taking the course. Additionally, during the course,

the tutor monitors and reacts to the knowledge and

affective states of the student; therefore, the course

is re-planned considering the new students

conditions and with base on the learning style rules.

5 CONCLUSIONS AND FUTURE

WORK

In this paper we presented an approach that will

allow us to integrate affective behavior and learning

styles of the students into intelligent environments to

complement the current approach in intelligent

tutors that follow what the student knows using a

model that tracks the knowledge state of the student.

The affective behavior and learning styles models

increase the degree of personalization of the

intelligent environments.

In the future we plan to implement and test our

approach using a training course for the IIE

postgraduate center and we plan to include the new

SCORM features that support intelligent tutors.

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