Evaluating the effectiveness of the implemented models of ICT tools in teaching mathematics.
Vrdoljak, Anton ; Banjanin, Milorad ; Rakic, Kresimir 等
1. INTRODUCTION
Analyzing and evaluating the effectiveness of some implemented
models of ICT tools in teaching mathematics, regarding the teaching of
complex numbers and interactive geometry, are problems of this paper.
The last decade of the 20th and the beginning of 21st century has
marked by the so-called digital revolution that has made major changes
in the world. These changes comes as a consequence of technological
progress, notably the progress of information and communications
technology (ICT), which greatly affects the education and radically
changing the existing process of teaching and learning in general. It is
therefore understandable that one of the most current subjects in
contemporary issues of teaching mathematics are teaching process and
learning of mathematics supported by ICT, among them an important place
belongs to the evaluation of the implementation models of ICT tools in
the teaching process of mathematics.
Thinking about the differences between teaching process and
learning of mathematics supported by ICT and traditional teaching
process and learning of mathematics, suggests that teaching process and
learning of mathematics supported by ICT has advantages or
preferabilities over traditional teaching process and learning of
mathematics.
The main reasons why we choose these subjects lies in our beliefs
that by teaching process and learning of mathematics supported by ICT
the student actually become a centre of the educational process, obtains
information from various sources, progress in acquiring new knowledge
pace that suits his abilities and knowledge and thoroughly understand
the master content of the curriculum.
However, highlighting the advantages or disadvantages are not
enough. Furthermore, no single paradigm is right for all
situations--content domain, subject matter, target learners, type of
assessments and the physical or virtual environment all play roles.
Therefore, to ensure a greater or lesser effectiveness of some methods
of teaching process or models of learning, it is necessary to conduct a
research on the effectiveness of these methods of teaching process
(models of learning), which is to be one of the goals of this paper. In
our research we encountered some limitations that may have a significant
impact on the obtained results. One of these limitations is the fact
that the experiment was conducted with a group of students on a
voluntary basis.
2. PROBLEM OVERVIEW
With the belief that learning theory should contribute to the
delivery and practice of learning, DeVilliers advocates so-called the
Hexa-C Metamodel (HCMm), what is an approach that integrates six
interrelated concepts from contemporary learning theory: cognitive
learning, constructivism, components, creativity, customization, and
collaborative learning--into a framework that serves both as a design
aid and as an evaluation approach for investigating existing resources
from the perspective of learning theory (DeVilliers, 2007).
Three of C's: constructivism, cognitive learning, and
components, are mainly theoretical components, while the others:
collaborative learning, creativity, and customization, are practical
methods used by educators to foster effective and affective learning.
Figure 1 shows the hexagonal framework of the HCMm, representing its
inter-related elements as merging segments around the hub of the
technology as a means of delivery and emphasizing the importance of
environment by embedding the whole within context.
According to DeVillier, when developing or investigating a
particular environment or artefact, the educator, educational web
developer, instructional designer, or evaluator should carefully
consider the six elements, determining which are relevant to the content
and context (DeVilliers, 2007). They should then consider to what
extent, and in what ways, those elements could be optimally implemented.
In other words, they should ensure that technology serves as a hub that
delivers the message and does not distract or detract from the message.
The design, development, implementation and evaluation of
e-learning can be enhanced by considering HCMm elements and applying
those appropriate to the context. No single paradigm is appropriate--no
'one size fits all'--but its elements can be translated into
principles, design guidelines, and evaluation criteria for different
domains and subject matter.
[FIGURE 1 OMITTED]
According to Bates there are several quality factors in the
educational content supported by technologies. In the context of higher
education institutions, they are content, multimedia production,
instructional design and implementation and support for students (Bates
& Poole, 2003). These elements should not be restricted only to
educational contents (materials) supported by technologies in higher
education institutions. Their significance also, with minor
modifications, may reflect the quality in the context of secondary
education through the use of e-education.
3. IMPLEMENTATION MODELS OF ICT TOOLS IN TEACHING OF COMPLEX
NUMBERS AND INTERACTIVE GEOMETRY
The text that follows will shortly describe some implemented models
of ICT tools in teaching mathematics, and planning research and
implementation of experiment. Within one year of educational-research
project conducted at the Faculty of Civil Engineering, University of
Mostar, we developed many modules or e-learning environments for
teaching mathematics on level of secondary and high schools. These
modules, written in Croatian, follow the ideas mentioned in problem
overview, as well as other developed modules (Vrdoljak et al., 2006). In
this paper we analyzed and evaluated the effectiveness of these two
modules:
* Complex numbers, placed on following address: http://www.
gfmo.ba/kompleksni_brojevi/
* Interactive geometry, placed on following address:
http://www.gfmo.ba/giak/
First of them is already described in detail in one other
scientific paper (Vrdoljak, 2009), and second too. These works point
only some of the educational potentials and possibilities afforded with
implemented models of ICT tools. Because our awareness regarding huge
transformations of the workplace for teaching and learning of
mathematics with an implemented models of ICT tools, for a main goal in
our educational-research project we set an examination--has developed
learning and teaching contents fully accomplish the profit of advantage
of learning and teaching with an implemented models of ICT tools, and a
determination--how to maximize motivational impact from ICT?
For the sample on which we have carried out research and realized
the experiment, we chose a group from a total of 105 students (the first
year of undergraduate civil engineering study in an academic 2008/2009
year at the Faculty of Civil Engineering, University of Mostar).
Students were assigned codes, and were divided into experimental (52
students) and control group (53 students), by a random selection.
The experimental group had one week of teaching and learning on a
set of complex numbers and geometry based on the module of complex
numbers and interactive geometry (implemented models of ICT-tools). The
control group did not have access to these modules, and has learned and
been taught (traditionally) from a previously received text material
(literature).
Upon completion of both weeks students of the experimental group
together with students of the control group wrote so-called flash-test
regarding the content of complex numbers and geometry. The test was
evaluated with points from 0 to 43, to see if there is any difference in
knowledge, or the speed of answering, consistency and safety in response
between the experimental and control groups, or to see are the teaching
and learning based on the implemented models of ICT tools (the modules
of complex numbers and interactive geometry) more efficient than
traditional teaching and learning in the process of teaching
mathematics.
4. RESULTS
Analysis of the results begins with the determination of whether
there is a statistically significant difference between control (in
Table 1. control group is marked as G2) and experimental groups (in
Table 1. experimental group is marked as G1) in the results regarding
the flash-test. In this regard, the first step is to set null hypothesis for the results from the flash-test H: There are no statistically
significant differences between experimental and control groups in the
results of flash-test.
As seen in table 1, value t = 5.65 is greater than 1.96, and value
p = 0.000 is less than 0.05, so the hypothesis H0 is rejected (not
accepted) and concludes that there is a statistically significant
difference between the experimental and control groups in the results of
flash-test. Therefore, according to the results of t-test, we can
conclude that any differences between the experimental and control
groups could not arise as a result of errors, or it could be
coincidental.
5. CONCLUSION
These general findings are in accordance with results of some other
referred authors (Christmann & Badgett, 2000). It is obviously that
this result we can thanks mainly to the integration and implementation
of observed models of ICT tools in teaching mathematics. Technology
brings to pupils and their teachers the opportunity to individualize learning--to generate illustrative examples, as well as dynamic and rich
presentation of a given subject, to follow interesting topics to the
desire depth, to choose their own problems and appropriate tools for
solving them. For our further research we will develop an interactive
educational web-portal with different mathematical contents. Comparing
with other countries in our neighbourhood, Bosnia and Herzegovina has to
move over a long way to reach them.
6. REFERENCES
Bates, A. W. & Poole, G. (2003). Effective teaching with
technologies in higher education: Foundation for success, Jossey-Bass,
ISBN 0-7879-6034-9, San Francisco
Christmann, E. P. & Badgett, J. L. (2000). The comparative
effectiveness of CAI on collegiate academic performance. Journal of
Computing in Higher Education, Vol. 11, No. 2, (March, 2000) 91-103,
ISSN 1042-1726
DeVilliers, M. R. (2007). The Six C's Frameworks for
e-Learning, In: Advanced principles of effective e-learning,
Buzzeto-More, N. A., (Ed.), 1-25, Informing Science Press, ISBN-10
1-932886-02-8, Santa Rosa
Vrdoljak, A.; Aoyama, K.; Yahara, H. & Isoda, M. (2006).
Development of Mathematics Learning Contents with ICT Focused on Complex
Number Contents of "Interactive Lessons", Proceedings of the
30th annual meeting of JSSE, Vrdoljak, A. (Ed.), 265-266, ISSN
0913-4476, Tsukuba, August 2006, Japanese Society for Science Education
JSSE, Tsukuba
Vrdoljak, A. (2009). Implementation models of ICT in teaching of
complex numbers, Proceedings of the 3rd Nordic EWM Summer School for PhD
Students in Mathematics, Vrdoljak, A. (Ed.), 251-256, ISBN
978-952-12-2278-8, Turku, June 2009, Turku Centre for Computer Science,
Turku
Tab. 1. Results of the t-test, arithmetic mean and standard
deviation for the flash-test
G1 Std. Std.
vs. Mean Mean Dev. Dev. F-ratio
G2 G1 G2 t-value P G1 G2 Var. p Var.
19.798 9.830 5.650 0.000 9.882 8.126 1.479 0.163
