guven.pdf


Australasian Journal of
Educational Technology

2012, 28(2), 364-382

Using dynamic geometry software to improve eight grade
students’ understanding of transformation geometry
Bulent Guven
Karadeniz Technical University

This study examines the effect of dynamic geometry software (DGS) on  students’
learning of transformation geometry. A pre- and post-test quasi-experimental design
was used. Participants in the study were 68 eighth grade students (36 in the
experimental group and 32 in the control group). While the experimental group
students were studying the transformation geometry in a  (DGE), the same instruction
was carried out with dotted and isometric worksheets with the control group students.
A 15 multiple choice Transformation Geometry Achievement Test and a 15 open ended
item Learning Levels of Transformation Geometry Test were used as pre and post-test. The
result of covariance analysis showed that the experimental group outperformed the
control group not only in academic achievement but also in levels of learning of
transformation geometry.

Introduction

As a result of dramatic changes in mathematics education around the world, in Turkey
both elementary and secondary school mathematics curricula have changed in the
light of new mandates since 2005. Previous curricula were under the hegemony of a set
of facts, formulas and procedures. Current curricula focus on the processes of
exploration, communication and conceptualisation through the classroom activities
rather than presenting a plethora of facts in traditional ways. The aim of the reform is
to establish inquiry mathematics. In contrast with traditional classroom activities that
emphasise repetition, practice, and other routinised means to reach some focused
endpoint, inquiry mathematics instruction emphasises student engagement in situated
mathematical problem-solving (Guven et al., 2009).

Recently, computer technology has emerged as a tool facilitating an important
paradigm in the development of mathematics curricula, suggesting its effectiveness for
accomplishing new demands in education (Sinclair, Renshaw & Taylor, 2004; NCTM,
2000). Accordingly, the use of computers in mathematics instruction has become a
basic element in the Turkish educational system, not as a standalone resource but as an
integral part of the teaching/ learning environment. The use of dynamic geometry
software (DGS) and computer algebra systems has been especially emphasised as an
important catalyst for achieving desired objectives. Technology classes found in almost
all schools are the first steps.

Dynamic geometry software

Since the 1990s, the contribution of technology to the teaching and learning of
geometry has been perceived mainly as strongly linked with dynamically manipulable,



Guven 365

interactive geometry software, such as Cabri and Geometer's Sketchpad.  The “dragging”
feature of DGS distinguishes it from other geometry software (Botana & Valcarce,
2003). Once a construction is completed, the user can drag certain elements of it, and
the whole construction behaves in such a way that specified constraints are
maintained, providing an environment in which students can experiment freely. They
can easily test their intuitions and conjectures in the process of looking for patterns and
checking the invariant properties of figures (Marrades & Gutierrez, 2000). Luthuli
(1996) characterised this type of instruction as research-based geometry. Because
specific instances can be varied easily by dragging, with results visible on the
computer screen, attention has tended to be focused on the software’s potential in
aiding the transition from particular to general cases  (Hoyles & Jones, 1998). This
inductive nature of the software gives students an opportunity to learn Euclidean
geometry via explorations that promote the conjecturing process (Stols & Kriek, 2011).
DGS has been regularly used worldwide for teaching and learning Euclidean geometry
for a long time. One of the learning fields in which this software is used efficiently is
transformation geometry, which is an important sub-learning area of the geometry
strand. DGS allows certain affine transformations (translations, reflections, rotations,
dilations) to act on figures or their parts. The role of DGS to understand the
transformations is stated by NCTM as follows:

Dynamic geometry software allows students to visualize a transformation by
manipulating a shape and observing the effect of each manipulation on its image. By
focusing on the positions, side lengths, and angle measures of the original and
resulting figures, middle-grades students can gain new insights into congruence.
Transformations can become an object of study in their own right. Teachers can ask
students to visualize and describe the relationship among lines of reflection, centers of
rotation, and positions of preimages and images. Using the interactive figure, students
might see that the result of a reflection is the same distance from the line of reflection
as the original shape. (NCTM, 2000)

In a dynamic geometry environment (DGE), transformations can be determined by
dynamic data, such as a rotation by moveable angle. These features help students
understand transformation geometry dynamically.

Some research studies investigated the effect of DGS on students’ achievement in
different geometry subjects. McCoy (1991) examined the effect of Geometric Supposer on
students’ ability to solve high-level problems, low-level problems and application
problems by designing an experimental study. The results showed that the scores of
students in experimental groups were significantly higher on the high-level and
application problems, although there were no significant differences on scores for low-
level problems. Erbas and Yenmez (2011) designed an experimental study to
investigate the effect of using the Geometer’s Sketchpad with open-ended investigations
of sixth grade students’ learning in polygons and congruency and similarity of
polygons. The results showed that the treatment created substantial improvement in
students’ achievement in the experimental group compared with students in the
control group. Furthermore, some studies have indicated a positive effect of using
dynamic geometry on students’ problem solving and posing (Christou et al., 2005), and
discovering and conjecturing (Aarnes & Knudtzon 2003; Habre 2009).

Geometric transformations

While there are many different kinds of geometric transformations, the focus of this
study is the concept of geometrical transformations encompassing the three



366 Australasian Journal of Educational Technology, 2012, 28(2)

transformations (translation, reflection, and rotation) of the plane. According to NCTM
(2000), “Instructional programs from pre-kindergarten through grade 12 should enable
students to apply transformations and use symmetry to analyze mathematical
situations.” (p.41).

According to Hollebrands (2003), there are three important reasons to study geometric
transformations in school mathematics: it provides opportunities for students to think
about important mathematical concepts (e.g., functions, symmetry), it provides a
context within which students can view mathematics as an interconnected discipline,
and it provides opportunities for students to engage in higher-level reasoning activities
using a variety of representations. Lauding its dynamic nature, Peterson (1973) pointed
out that transformation geometry encourages students to investigate geometric ideas
through an informal and intuitive approach. This approach stresses sensitivity,
conjecturing, transformation and inquisitiveness. Transformation can lead students to
exploration of the abstract mathematical concepts of congruence, symmetry, similarity,
and parallelism; enrich students’ geometrical experience, thought and imagination;
and thereby enhance their spatial abilities.

Research suggests that students should have a sufficient knowledge of geometric
transformations by the end of eighth grade in order to be successful in higher level
mathematics studies (Carraher & Schlieman, 2007; NCTM, 2000). For these reasons
there is significant support for the incorporation of geometric transformations in a
school geometry courses (Hollebrands, 2003). However, studies showed that students
have difficulties in understanding the concepts and variations in performing and
identifiying transformations including translation, reflection, rotation and
combinations of transformations of these types (Clements & Burns, 2000; Edwards,
1990; Olson, Zenigami & Okazaki, 2008; Rollick, 2009). For example, Edwards (1989),
found that middle school students encounter difficulties in both executing and
identifying transformations. Execution errors including drawing images of reflections
in the wrong orientation and out of scale. In these studies, it was concluded that whilst
most students have an operational understanding of transformations, most have not
developed a conceptual understanding. Some researchers (e.g. Edwards, 1989) have
seen dynamic representations as a powerful tool to improve students’ understanding
from operational to conceptual.

Geometric transformations in Turkish elementary mathematics curriculum

The first five years of the Turkish elementary mathematics education curriculum
comprises four basic strands: Numbers, Geometry, Measurement and Data. In the
geometry strand, students gradually learn basic transformations as a sub-learning
domain from the second to the eighth grade. In other words, transformation geometry
subjects are not packed into one year but spread over seven grades. First,  second
grade students learn to explain symmetry by using the modals around a straight line.
Third grade students learn to determine whether or not a given shape has a symmetry
line by folding and to generate symmetric shapes themselves, while fourth grade
students learn to determine the symmetry lines of plane shapes without folding. In the
fifth grade, students learn to determine the symmetry lines of polygons and to draw a
given plane shape’s symmetry according to the symmetry line. The modals used in
activity samples related to each grade in the curriculum are shown in Table 1.



Guven 367

Table 1: Samples related to transformation geometry in the Turkish
mathematics education curriculum, grades 2-5.

Grade Sample
2.

3.

4.

One reflection line
5.

Four reflection lines    Six reflection lines

The Turkish elementary mathematics education curriculum guide for the first five
grades presents the structure of transformation geometry instruction as follows:

Beginning from the 2nd grade symmetry as a sub-learning domain is brought into
program with pursuing a certain development. Appropriate environments for
students to differentiate the symmetry and axis of symmetry on concrete models by
folding and cutting activities should be provided. In the 4th and 5th grades, that
geometric shapes may have more than one axis of symmetry is to be handled for a
while after the students have reached a certain levels. (TTKB, 2004, p.29)

As can be seen, although the basics of transformation geometry are included in the 1-5
elementary mathematics education curriculum, a complete formal beginning is not.
Also, at these levels teachers are not supposed to make use of DGS while they are
explaining the concepts of transformation geometry.

The 6-8 grade elementary mathematics education curriculum consists of five basic
strands: Numbers, Geometry, Measurement, Probability and statistics, and Algebra. In
the geometry strand, concepts of transformation geometry are taught formally and in
detail from the sixth through eighth grades. In this context, sixth grade students learn
to explain translation and construct the image of a shape that is formed as the result of
translation. Seventh grade students learn to explain reflection and rotation and to draw



368 Australasian Journal of Educational Technology, 2012, 28(2)

the rotation of shapes around a dot in a line according to an angle that is stated. In the
eighth grade, students learn to make composite transformations and to associate the
transformations that they have made along an analytical line with coordinates. Models
used in activity samples for each grade in the 6-8 elementary mathematics education
curriculum are presented in Table 2.

Table 2: The samples that are related to transformation geometry
in Turkish grades 6-8 mathematics curriculum

Grade Sample
6

7

8

As can be seen, students learn the basic transformations formally between the sixth
through eighth grades. Also the curriculum guide recommends that teachers make use
of DGS during the teaching of transformation geometry subjects. However, research
has shown that the teachers have not been using this software in their classes (Guven
et al., 2009).

Learning transformation geometry in a computer environment

Only a few research studies have examined students’ understanding of geometric
transformations while using technology (Edwards, 1992, 1997; Edwards & Zazkis,
1993; Johnson-Gentile, Clements & Battista, 1994). These studies have utilised Logo



Guven 369

programming language and DGE. Edwards (1992),  introduced twelve middle school
students to translations, reflections and dilations in a Logo environment and
concluded that it could be used successfully to help students view translations,
reflections, and rotations as objects themselves, and the Logo geometry environment
could help students to construct concepts of transformation geometry. Johnson-Gentile
et al. (1994) compared data on fifth and sixth grade students’ learning of
transformation geometry in Logo and non-Logo environments and concluded that the
Logo treatment students were more likely than the non-Logo treatment students to
discuss the transformations instead of the figures to which the transformations were
applied.

These early studies provide evidence that teaching geometric transformations to
students in a technological environment is feasible and may have positive effects on
students’ learning of mathematics. Moreover, these early studies did not have the
advantage of more sophisticated computing tools that are now available (Hollebrands,
2003). The software programs that were used in these studies were static in nature.

The impact of DGS on students’ learning of transformation geometry has been
investigated mostly with secondary students and teacher trainees. Some support for
the potential of DGE is found in the experimental work of Dixon (1997), who found
that dynamic geometry group students were more successful than students in a control
group, at identifying and applying reflections and rotations. Hollebrands (2003)
investigated the nature of secondary students’ understanding of geometric
transformations, which included translations, reflections and rotations, in the context
of DGE. Students’ conceptions of transformations as functions were analysed using the
APOS  theory (Action-Process-Object, Schema, an extension of Piaget's theory of
reflective abstraction applied to the learning of mathematics). The findings showed
that while initially all students appeared to reason about transformations as motions,
which may have been connected to reasoning about drawings and an action
conception, an essential understanding in students’ movement toward reasoning about
transformations as functions was their understanding of domain.

Harper (2002) investigated four pre-service elementary school teachers’ knowledge
about geometric transformations in DGE. The major findings were that the
participants’ vocabulary become more sophisticated, incorporating formal
mathematical terminology; all participants were able to construct the reflected image
of a figure and a line of reflection based on the properties of reflections; participants
were more knowledgeable with the use of a vector to represent a translation’s direction
and magnitude; participants were able to identify the centre and angle of a single
rotation to map a figure with its rotated image; and the DGS provision of immediate
visual feedback helped the participants to conjecture, test and revise  their solutions.

Theoretical framework

In the 1950s, two Dutch educators, Dina and Pierre van Hiele, developed a structure
for reasoning that they suggested may reflect how children learn geometry. According
to the van Hieles, the learner, assisted by appropriate instructional experiences, passes
through the following five levels, each of which depends on successful achievement of
the previous levels (Fuys, Geddes & Tischler, 1988):



370 Australasian Journal of Educational Technology, 2012, 28(2)

Level 1: Recognition The student recognises geometric figures by their global
appearance, identifies names of figures, but does not
explicitly identify their properties.

Level 2: Analysis The student analyses figures in terms of their components
and properties, discovers properties and rules of a class of
shapes empirically, but does not explicitly interrelate figures
or properties.

Level 3: Pre-deductive The student logically interrelates previously discovered
properties and rules by giving or following informal
arguments.

Level 4: Deductive The student proves theorems deductively, develops
sequences of statements to deduce one statement from
another, but does not yet recognise the need for rigour.

Level 5: Rigour The student establishes theorems in different axiomatic
systems and analyses and compares these systems.

Crowley (1987) described the distinctive characteristics of the five levels of the van
Hiele model as follows: (1) The model is sequential in that a learner cannot function at a
higher level without first progressing through the thought processes of all previous
levels; (2) progress from one level to the next is not through biological development but
rather depends on instruction; (3) the linguistic symbols of each level are unique, that
is, each level is regarded as having its own language, and learners on different levels
cannot understand one another; (4) the intrinsic characteristics of one level become the
extrinsic objects of study of the next; and (5) the mismatch between the level of
instruction and the level at which a student is functioning may restrict the desired
progress.

Similarly, Soon (1989) determined van Hiele-like levels for learning in transformation
geometry. The characteristics of these levels are shown in Table 3.

Table 3: Levels of understanding in transformation geometry

Levels Characteristics: The student ...
Level 1 • identifies transformation by the changes in the figure; (a) in simple drawings of

figures and images; and (b) in pictures of everyday applications.
• identifies transformation by performing actual motion; names, discriminates the

transformation.
• names or labels transformations using standard and/or non-standard names and

labels appropriately.
• solves problems by operating on changes of figures or motion rather than using

properties of the changes.
Level 2 • uses the properties of changes to draw the pre-image or image of a given

transformation.
• discovers properties of changes to figures resulting from specific transformation.
• uses appropriate vocabulary for the properties and transformation.
• is able to locate axis of reflection, centre of rotation, translation vector and centre of

enlargement.
• relates transformations using coordinates.
• solves problems using known properties of transformations.



Guven 371

Level 3 • performs composition of simple transformations.
• describes changes to states (pre-image, image) after composite transformations.
• represents transformations using coordinates and matrices.
• interrelates  the properties of changes to a figure resulting from transformations.
• given initial and final states, can name a single transformation.
• given initial and final states, can decompose and recombine a transformation as a

composition of simple transformations.
Level 4 • gives geometric proofs using transformational approach.

• gives proofs using the coordinates and matrices.
• thinks through multi-step problems and gives reasons for problems.

Level 5 • understands – associative, commutative, inverse, identity with respect to a
composite transformation operation.

• identifies groups of transformations.
• proves or disproves subsets of transformation from group structures.

Soon (1989), after diagnosing the levels and applying a Guttman Scologram analysis,
indicated that they have a hierarchical structure. As it can be seen in Table 3, levels 4
and 5 are well above the expected performance level of elementary school students.
Accordingly, only the first three levels are relevant in the present study, which was
carried out with elementary school students.

Purpose of the study

Battista (2007), in his review about the geometric thinking, highlighted that qualitative
research results have already revealed that superior geometry learning can occur with
the use of DGS;  however, quantitative research results are needed to generalise these
results and determine whether using DGEs is “better” than using traditional paper and
pencil methods (p.884). Similarly, we don’t have enough quantitative evidence for
using DGS for geometric transformation subjects. Thus, the purpose of this study is to
determine the effect of the DGS Cabri (http://www.cabri.com/, Turkish language
version) on eighth grade students’ academic achievement and levels of understanding
in transformation geometry. More specifically, the research question of the study was
as follow: What is the effect of using DGS on eight grade students’ academic
achievement and levels of understanding of geometric transformations compared to
paper and pencil methods?

Method

Participants

The participants in the study were 68 eighth grade students ranging in age from 14 to
15 years, from two different classes of a transformation geometry course in a school
located in Trabzon, Turkey. There were 36 students (21 boys and 15 girls) in the
experimental group, a class which was taught using DGS, and 32 students (17 boys
and 15 girls) in the control group, which was taught using isometric and dotted
worksheets. Purposive sampling was used to situate the study in a school that was
well equipped in terms of computer laboratories and technological devices.

The study was carried out during the spring semester of the 2008/2009 academic year.
The classes were randomly assigned as either experimental or control groups.
Although they were eighth grade students, both classes studied all the transformations
taught in the sixth through eighth grades.



372 Australasian Journal of Educational Technology, 2012, 28(2)

Instruments

The Transformation Geometry Achievement Test (TGAT) and the Learning Levels of
Transformation Geometry Test (LLTGT) were used as data collection instruments in this
study.

Transformation Geometry Achievement Test (TGAT)

This multiple choice geometry achievement test, initially consisting of 20 questions
covering translation, rotation and symmetry, was designed by the researchers to
measure students’ learning of transformation geometry. The test was based on the
student text books and teacher guides for sixth, seventh and eighth grades distributed
by the Ministry of National Education. The researchers designed the test taking into
account student levels, student achievement in the pre-transformation learning
domain, and the aims of the study.  The completed questions were then examined by
two teachers with more than ten years’ experience and revised in accordance with their
feedback. In its final version, the test was administered as a pre- and post-test before
and after the study.

A pilot study using the TGAT was conducted in Autumn 2008, with 53 eighth graders
in the same school. As a result of reliability analyses made after pilot applications, 5
items with low reliabilities were removed from the TGAT. However, care was taken to
not disrupt content validity. The Spearman-Brown reliability coefficient of the final
form was r=0.81. Three of the questions covered translation, four covered rotation, four
covered symmetry, and the rest covered composite transformations. Sample questions
for each transformation are shown in Table 4.

In order to determine students’ levels of understanding in transformation geometry, an
open ended test which Soon (1989) had developed during his doctoral studies at
Florida University was used. The original version of the test includes four questions at
the first level, ten questions at the second level, nine questions at the third level and
eight questions at the fourth level. Because the students in the sample were eighth
grade students, the fourth and fifth levels of this test were not included in our study.
Also, in keeping with the Turkish Mathematics education curriculum, the test was
revised to include five questions in each level, which involved removing some
questions in the second and third levels and adding a new question to the first.  A pilot
study was conducted to evaluate the effectiveness of this open ended test in
determining students’ learning of transformation geometry. In pilot study, the test was
administered to twelve eighth grade students, chosen by the researchers to represent
different levels, at the end of the learning period. Two weeks later, clinical interviews
with the same questions were conducted with the same students, whose levels were
determined according to the results of the interviews. Over the course of clinical
interviews, questions were presented to learners and learners were asked to think
aloud while solving the problems. The researcher directed new questions to learners
regarding the solution when deemed to be necessary. Questions directed to learners
were shaped especially around the question “why”. By this means, mathematical
process behind the action carried out by the learner was tried to be revealed. These two
sets of results were compared and it was found that 10 of the 12 students’ clinical
interview results were consistent with their open ended test results, indicating that this
15-item open ended data collection instrument could be used with 83% reliability. The
LLTGT was also used as a pre- and post-test in the study. Samples of the open ended
questions which were used in this test are shown in Table 5.



Guven 373

Table 4: Some of the items in TGAT
Question Transformation

Translation

Reflection

Rotation

Translation and
reflection

Translation in
the coordinate

plane

Reflection in
the coordinate

plane



374 Australasian Journal of Educational Technology, 2012, 28(2)

Table 5: Sample questions for each levels of LLTGT
Level Sample question Description

1. She/he can
describe the
translation
according to the
changes in the
shape.

2. She/he can find
out the coordinate
points by
associating the
translation with
the points.

3. Deriving from the
given position of
beginning and
ending, She/he can
identify it as one
translation.

Procedure

Treatment of the experimental group

Before the treatment, students in the DGS group were trained on how to use Cabri
software since it was new for them. Students learned the functions of the buttons, such
as how to draw a line, segment, and form a polygon etc.; how to drag and construct
bisectors; and how to measure length, area, angle, etc. The teacher spent four class
hours on teaching Cabri. During this four hour period, no application regarding
geometric transformations was made with learners. Only technical characteristics and
basic use of the software were summarised in the courses. Pre-tests, which were the
precautions to prevent this four hour period from becoming a reason for differences
between learners, were applied after the phase of introducing the software which
lasted for 4 hours. The students in this group used the features of Cabri software to
study the worksheets that were handed out for lessons. Also, these students studied



Guven 375

their own transformations on the computer independently from the worksheets. The
dynamic feature of the software enabled students to easily study the different type of
transformations and observe the dynamic effects of change on the main object on the
image object. For instance, as shown in Figure 1, the students could easily change the
angle and rotation point in rotation and observe the effects of the change.

Figure 1: Screen pictures, examples of rotation in DGE

Direct information was not presented on the worksheets which were given to students.
The students were supposed to perform transformation applications and observe their
effects. Also, they were supposed to write the observation results in the related places
on the worksheets. In this group an exploratory approach was followed according to
the features of transformation. During the course of application made with
experimental group, learners studied in groups with two learners due to the limited
number of computers. Generally, during these applications, learners experienced:

• Step by step construction of a transformation in the Cabri environment in
accordance with the instructions written on worksheets.

• Dynamic observation of the transformation by dragging geometric objects (e.g.
changing symmetry line or point or rotation angle).

• Exploring the characteristics of the transformation, confirmation of the exploration
and explanation in the relevant section of the worksheet.

• Discussion of the obtained results in the classroom.
• Making the transformations written in worksheets according to the information

obtained after classroom discussion and confirmation with Cabri.

As it is seen, DGS was used as an instrument to explore the characteristics of the
transformation, test the discovered characteristics and observe the transformation
dynamically over the course of applications. Besides, learners were granted with the
opportunity to practise and test what they learnt on computer screen and check their
learning accordingly. In this process, the classroom teacher acted primarily as a
facilitator with the role of organising the classroom discussions.



376 Australasian Journal of Educational Technology, 2012, 28(2)

Treatment of the control group

In the transformation geometry application which was conducted with the control
group students, mostly dotted, isometric and platting worksheets were used
depending on the structure of transformation. The material taught in this group
paralleled the material taught in the experimental group, but all activities that were
carried out interactively in the computer environment were completed by the control
group students using pencil and paper. During the course of applications made with
the control group, learners studied in groups with two learners as did experimental
group students. Generally during these applications, learners' experiences paralleled
the experimental group students:

• Step by step construction of transformation with dotted isometric paper and pencil
in accordance with the instructions written on worksheets.

• Exploring the characteristics of the transformation, confirmation of the exploration
and explanation in the relevant section of the worksheet.

• Discussion of the obtained results in the classroom.
• Making the transformations with paper and pencil written in worksheets according

to the information obtained after classroom discussion.

In order to prevent the teacher from being the source of possible differences between
academic achievements and comprehension levels of groups, courses were given by
the same teacher to both experimental and control groups. The teacher conducting the
research had 6 years of teaching experience and holds a Master of Science degree in
mathematics education. Thus, it is possible to say that the teacher was qualified
enough to use both DGS and other educational materials, as he had courses about DGS
and worksheets in his education. Also, the teacher, who participated voluntarily in the
study, was not an author of this research.

Applications lasted for 8 hours in both groups. Of these 8 course hours, 2 hours were
for translation and reflection, and 2 hours were for rotation transformations (learners
studied these transformations in sixth and seventh grades, in a traditional
environment). The remaining 4 hours were reserved for composite transformations,
and reflection and translation transformations on analytical plane. Despite the fact that
eighth grade students are only responsible for composites of transformations and
transformations made on analytical plane, transformations taught in sixth and seventh
grades were re-taught, to remind learners about their previous knowledge and to
progress this knowledge.

Data analysis

The TGAT consists of 15 multiple choice questions about transformation. For every
correct answer one point and for every wrong or blank answer no point was given,
resulting in a possible range of 0 to 15 points.

The LLTGT consists of 15 open ended geometry questions. All participants’ answer
sheets from LLTGT were read and scored independently by two researchers (one being
the author). After the analysis, these researchers together decided upon students’
levels of understanding.  All participants received a score for each van Hiele level
according to Usiskin’s (1982) grading system. The criterion for success at any given
level was four out of five correct responses. In this study, a student was given or
assigned a weighted sum score for LLTGT in the following manner:



Guven 377

1 point for meeting criteria on items 1-5 (Level-I)
2 points for meeting criteria on items 6-10 (Level-II)
4 points for meeting criteria on items 11-15 (Level-III)
This means that possible range of scores was 0 to 7 points.

The SPSS statistical package program was used to analyse the data obtained from the
TGAT and LLTGT scores. Frequency tables were constructed for LLTGT scores to
capture detailed information about distributions of participants’ Van Hiele levels. An
independent sample t-test was performed for pre-LLTGT and TGAT scores of the
experimental and control groups. In order to observe any significant differences in the
post-test scores, a covariance analysis (ANCOVA) controlling for the pre-test was
carried out.

Results

Is there any meaningful difference in the students’ TGAT scores?

As seen in Table 6, the results of an independent t-test showed no statistically
significant difference in pre-TGAT scores between the experimental group (M = 9.83,
SD = 1.59) and the control group (M = 9.18, SD = 2.92) [t (66) = 1.148, p > .05]. Therefore
this result showed that groups were at the same level in all concepts prior to
implementation and thus exhibited comparable characteristics.

Table 6: Descriptive analysis of groups’ TGAT scores

Pre-test Post-testGroup n M SD M SD
Experimental 36 9.83 1.59 13.22 2.01
Control 32 9.18 2.92 11.87 2.43

In order to compare the effects of instructional strategies administered to the groups
on post-test scores using ANCOVA, a test of homogeneity of within groups regression
slopes was conducted. As a result of the analysis, Group * pretest [F (3, 64) = .511, p >
.05], within groups slopes were found to be homogenous.

Table 7: Results of the covariance analysis of TGAT scores

* Estimated marginal means for post-testVariable Group M* Std. error
Mean

difference df F p
Partial eta
squared

Experimental 13.03 .28TGAT
score Control 12.08 .30

.946 1-64 5.111 .027 .073

The result of the ANCOVA related to TGAT scores indicated significant overall
treatment effects, controlling for pretest [F (1, 65) = 5.111, p < .05]. As seen Table 7,
students in the experimental groups benefited significantly more than those in the
control groups [mean difference = .946, p < .05]. Effect sizes calculated were partial eta
squared = .073. If these effects are evaluated according to Cohen’s (1988)
interpretations, it can be stated that the DGS-based instruction method had a moderate
effect on students’ geometry achievement.



378 Australasian Journal of Educational Technology, 2012, 28(2)

Is there any meaningful difference in students’ understanding of transformation
geometry levels?

As seen in Table 8, the results of an independent t-test showed no statistically
significant difference in pre-test LLTGT scores between the experimental group (M =
2.36, SD = 1.97) and the control group (M  = 2.18, SD = 1.92) [t (66) = .366, p > .05].
Therefore, this result showed that groups were at the same level in all concepts prior to
implementation and thus exhibited comparable characteristics.

Table 8: Descriptive analysis of groups related to LLTGT scores
Not

attained Level-1 Level-2 Level-3
LLTGT
scoreTest Group n

f % f % f % f % M SD
Experimental 36 3 8.3 15 41.7 14 38.9 4 11.1 2.36 1.97Pre-test
Control 32 4 12.5 13 40.6 12 37.5 3 9.4 2.18 1.91
Experimental 36 0 0.0 6 16.7 16 44.4 14 38.9 4.22 2.35Post-test
Control 32 1 3.1 8 25.0 17 53.1 6 18.8 2.96 1.93

In order to compare the effects of instructional strategies used with the groups on post-
test LLTGT scores using ANCOVA, a test of homogeneity of within groups regression
slopes was conducted. As a result of the analysis, Group * pretest [F (3, 64) = .023, p >
.05], within groups slopes were found to be homogenous.

Table 9: The results of the covariance analysis on LLTGT scores
* Estimated marginal means for post-testVariable Group M* Std. error

Mean
difference df F p

Partial eta
squared

Experimental 4.151 .226LLTGT
score Control 3.049 .240

1.103 2-65 11.183 .001 .147

The result of the ANCOVA related to LLTGT scores indicated significant overall
treatment effects, controlling for pretest [F (2, 65) = 11.183, p < .01]. As seen Table 9,
students in the experimental groups benefited significantly more than those in the
control groups [mean difference = 1.103, p < .01]. Effect sizes calculated were partial eta
squared = .147. If these effects are evaluated according to Cohen’s (1988)
interpretations, it can be stated that the DGS-based instruction method had a high
effect on students’ levels of understanding of transformation geometry.

Discussion and conclusions

In this study, the effect of DGS on the students’ academic achievement and their level
of understanding of transformation geometry was examined using a quasi-
experimental research design.

The results of the TGAT administered to the experimental and control groups at the
beginning of the study revealed that there was no meaningful difference in pre-
learning between the two groups. Administering the same test at the end of the study
revealed that there was a significant difference in favor of experimental group. This
result shows that DGS has a positive effect on the academic achievement of students.
There may be several reasons explaining this effect. The processes of controlling of
their own learning pace and carrying out their ideas and actions on a computer screen
can positively affect students’ learning. In the DGS learning environment students can



Guven 379

easily change the symmetry lines, symmetry centre points, geometric shapes and
rotation angles. They also can observe the effects of the changes on symmetry. This
treatment enabled the students to understand and interiorise the nature of change.
Moreover, studying transformations designed by themselves without reference to
worksheets, choosing and designing the elements necessary for performing a
transformation on a computer screen such as screen angle measure and symmetry line,
can lead students to develop an advanced understanding of transformation.

The findings of this study are consistent with conclusions reached by Hollebrand
(2003), who found that over time the students interiorised the acts they had performed
on a computer screen in a study carried out in a technological environment, in which
students’ understanding of transformation geometry was analysed according to APOS
theory. Moreover, Hollebrand (2003) revealed that the acts contributed to students’
ability to construct explanations about transformation geometry. However, the
students in the control group did not develop dynamic understanding of
transformations. Because they did their transformations on isometric and platting
worksheets, these students could not observe dynamically multiple instances of how a
change of basic elements can cause a change in transformations. For instance, they
could not observe directly the change of symmetry. Also, they only examined
transformation angle in the change of symmetry, and they performed transformations
only on the limited number of samples that were presented to them.

In the present study, the experimental group students could define their mistakes by
observing  the coherence between the geometric shape they obtained on the computer
screen and their expectations before the application. Thus they received feedback from
the computer and could discuss this feedback with the classroom teacher. However,
the control group students, after designing their transformations on the paper, could
decide whether or not their drawings were correct only when they received feedback
from their teacher. This case may have an active role on the difference generated in the
meaning of achievement. The experimental group’s opportunity to generate their own
feedback on computer screens may have been a major factor in the difference in
achievement between the two groups. Baki et al. (2011) found that using DGS and
generating their own feedback made a crucial contribution to pre-service teachers’
cognitive development. A similar contribution to younger learners’ cognitive
development is an implication of this study.

Different research results are reported in the literature on the contributions of DGS
learning environments to the development of students’ geometric thinking. While
some studies have reached the conclusion that DGS has raised the levels of students’
geometry understanding (Sang Sook, 1999, Breen, 1999), some have found no
important effect (Johnson, 2002; Larew, 1999). However, no previous study has
investigated the effect of DGS on students’ levels  of understanding of transformation
geometry. The present study has helped fill this gap by showing that DGS increased
eighth grade students’ levels of understanding of transformation geometry.

Before the application, the results of the LLTGT  showed that the experimental and
control group students were primarily in the first and second levels. That is, some
students could recognise transformations and had information about some features of
transformations. Considering the Turkish elementary mathematics education
curriculum, emphasising the features of the transformation, this level of understanding
was to be expected. Before the application, very few students were in the third level,
indicating that the great majority could not apply combinations of transformations,



380 Australasian Journal of Educational Technology, 2012, 28(2)

make connections between transformations, and associate transformations with
coordinates. After the application, 38.9% of the students in the experimental group had
reached the third level (from 11.1% to 38.9%), while the number of students at the first
level decreased markedly (from 41.7% to 16.7%) and almost half were in the second
level (44.4%). This finding demonstrates that the DGS application had a positive effect
on the experimental group’s levels of understanding of transformation geometry. On
the computer, the experimental group students were able to make many different
transformations on the same geometric shape in succession. This observation indicates
that many students increased their competence in understanding combinations of
transformations and making connections between transformations. In addition, the
opportunity to observe dynamically the features of geometric transformations in an
exploratory environment increased students’ understanding of these features.

As the outcomes from this study show, a curriculum enriched by DGS can significantly
improve not only the academic success of students but also their levels of
understanding of transformation geometry. Hence, mathematics teachers should be
encouraged to use this software in their classes. After this experimental study,
informal interviews with the teacher of experimental and control groups in this study
showed that the teacher continued to use DGS actively in his different courses for
different topics in the 2010-2011 academic year. Towards this end, teachers should be
introduced to the software in pre-service and in-service courses, in order to experience
its effects on their own learning, and educated in the design of computer-based
mathematics learning environments. We further recommend qualitative research to
investigate in depth the roots and causes of the effects obtained in this study.

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Author: Associate Professor Dr Bulent Guven
Department of Secondary School Science and Mathematics Education, Fatih Faculty of
Education, Karadeniz Technical University, Sogutlu, Akcaabat, Trabzon, Turkey
Email: bguvenktu.edu.tr, guvenbulent@gmail.com

Please cite as: Guven, B. (2012). Using dynamic geometry software to improve eight
grade students’ understanding of transformation geometry. Australasian Journal of
Educational Technology, 28(2), 364-382.
http://www.ascilite.org.au/ajet/ajet28/guven.html