International Journal of Interactive Mobile Technologies (iJIM) – eISSN: 1865-7923 – Vol. 14, No. 18, 2020


Paper—Effect of Teaching Geometry by Slow-Motion Videos on the 8th Graders’ Achievement 

 

Effect of Teaching Geometry by Slow-Motion Videos on 

the 8th Graders' Achievement 

https://doi.org/10.3991/ijim.v14i18.12985 

Mohammad Ahmad al khateeb () 
Hashemite University, Zarqa, Jordan 

mkm7879@hu.edu.jo 

Ahmed Mohammad Alduwairi 
AL-Albayt University, Mafraq, Jordan 

Abstract—This study aims to investigate the effect of slow-motion videos 

use on the 8th graders' achievement in geometry and identify the students' views 

about the slow-motion. The study was carried out in a quasi-experimental envi-

ronment on 74 eighth graders of two different classes. One of the classes was 

designated as the experimental group (n=38). The other class (n=36) were desig-

nated as the control group, the results showed that the achievement level of the 

students who attended the geometry lessons using the slow-motion mode was 

higher than those who attended the traditional method lessons. Furthermore, the 

results showed that the experimental group students found that learning through 

slow-motion was information, easily understandable,  beneficial,  instructive,  

stimulating, enjoyable, very creative. 

Keywords—Bruner Model, Geometry, Lesh Model, Mathematical Achieve-

ment, Slow-motion 

1 Introduction 

Slow-motion animation videos (SMV) are a new teaching method, developed over 

the last decade in the classes of science teaching in Wollongong University (Hoban, 

2009, 2005; Hoban and Nielsen, 2011). Animations are among the most used technol-

ogies in teaching, and most affecting and attractive of the children's attention, and thus 

could be invested in their teaching (Hoban, Ferry, Knoza & Vialle, 2007, McKnight, 

Hoban & Nielsen, 2011). 

Therefore, this study is seeking to develop the geometry and measurement unit of 

the eighth basic grade, based on the slow-motion animation technology. The study de-

pends on its theoretical framework on Bruner's model (1966), and on the model of Lesh, 

Cramer, Doerr, Post & Zawojewski (2003) for the intellectual representations. It also 

relies on the cognition model of the technological, pedagogical content knowledge 

framework (T-Pack). 

Bruner argues that good knowledge focuses on understanding rather than perfor-

mance. This means that it is not sufficient to obtain knowledge (with the concepts, facts 

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mailto:mkm7879@hu.edu.jo


Paper—Effect of Teaching Geometry by Slow-Motion Videos on the 8th Graders’ Achievement 

 

and principles it includes) the way it is represented, but it should be organized so that 

the individual could expand and deepen his/her knowledge, and transmit what he/she 

learned to other life situations (Takaya, 2008). 

In this concern, Bruner sees that the teacher's role is to translate what could be taught 

into a form that suits the learner's intellectual level, so that he/she will absorb it (Bruner, 

1966). Bruner places great attention to the active aspect of learning, where the learner 

is able to interpret his/her procedures and thinking ways, relying on his/her own learn-

ing style. He is also interested in how to represent the concepts the learner attempts to 

acquire through practice, in order to develop his/her ability to process the information 

he/she obtains. 

In a related context, Lesh highlights the role played by the external representations 

(all the items presented to the learner, such as pictures, drawings, paintings, tables, 

models, and symbols to learn a certain concept), and the internal representations (intel-

lectual images the learner builds about the math concepts and ideas), to enhance the 

acquisition and understanding of mathematical concepts (Chahine, 2011; Lesh, Cramer, 

Doerr, Post & Zawojewski, 2003). 

The technological, pedagogical content knowledge framework (T-Pack) refers to 

knowledge in three main domains (content knowledge, technological knowledge, and 

pedagogical knowledge). It is a framework to understand and describe types of 

knowledge the teachers need to provide an active pedagogy in a technology enhanced 

learning environment. This model aims at explaining the efficiencies the teachers need 

to enable them to integrate technology into teaching (Doering, Valestianos, Scharber & 

Miller, 2009, Niess et al., 2009; Harris & Hofer, 2011). 

Slow-motion animations, in their content, seek to employ this model to contribute to 

the increase of the students' participation and their understanding of the content (Keast, 

Cooper, Berry, Loughran & Hoban, 2010; Paige, Bentley & Dobson, 2016). They use 

technology to represent and explain certain content through suitable drawings and pic-

tures to conceptualize the ideas and explain the content, including its knowledge and 

concepts in an organized matter, which attracts the students and trigger them to unleash 

the imagination (Hoban, 2007; Hoban & Nielsen, 2014). This technology is further in-

terested in linking the previous knowledge with the context of daily life (Hoban & Niel-

sen, 2014). 

Gambari, Falode & Adegberro, (2014) conducted a study to verify the effectiveness 

of the computerized animations on the students' achievement in mathematics and re-

taining what they learnt at the long run. The results showed that the performance of the 

students who studied using the computerized animations was better than their peers 

who studied the same topic through the traditional way. Kaplan & Ozturk (2015) carried 

out a study to identify the effect of the educational animations on the 6th graders' 

achievement in the division and primary numbers subjects. The results showed that 

those who studied using the animations outperformed the others who did not use them 

in studying these subjects. 

In a related issue, Chu (2012) used animations in his teaching, and the results pro-

duced three perspectives. First, animations provided a positive classroom environment, 

and the students' performance was better in the tasks and activities they carried out. 

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Paper—Effect of Teaching Geometry by Slow-Motion Videos on the 8th Graders’ Achievement 

 

Second, it created a new teaching method in which there is a type of effective partici-

pation, followed by a discussion with the other students. Third, it assisted in utilizing 

the class time more efficiently, and made the student more focusing during the course 

of the class. 

The study of Akhas, Burut & Yulsel (2011) aimed at verifying the effect of anima-

tions and different computer activities on the students' achievement in the patterns. Ac-

cording to the study results, there was an increase in the students' academic perfor-

mance, who studied using animations and computer activities about the patterns. 

The current study emphasizes the use of slow-motion animations in math teaching, 

especially the geometry subjects. In spite of the importance of geometry, yet it is the 

most difficult math subject for the students. Many studies pointed out that students of 

different educational stages suffer from or are weak in geometry learning. This may be 

attributed to many reasons related to the general weakness in possessing fundamental 

math requirements, such as the difficulty of the geometry subjects in the textbook; poor 

abilities of the teacher in teaching it; lack of the student's basic concepts in geometry; 

student's inability to link geometry with the daily life; and use of traditional methods, 

instead of the modern methods that make geometry teaching-learning more interesting 

(Berch & Mazzocco, 2007, Tambychik & Meerah, 2010). 

Accordingly, this study represents an attempt to use modern teaching modes to im-

prove the students' level in mathematics, in general, and geometry in particular. Fur-

thermore, the study aims to answer the following two questions: 

1. What is the effect of slow-motion animation use on the 8th graders' achievement in 

the geometry subject? 

2. What are the students' perspectives about the use of animations in geometry teach-

ing? 

The significance of this study is in that it contributes to the utilization of an 

aspect widely loved by the children, which does not need more enhancements to 

use, namely, the passion and attachment of these children to the mobile devices, 

and using them as a means to keep abreast to the scientific development (Ekici, 

Cakmak & Ekici, 2014). Therefore, this study employed the slow-motion anima-

tions technique as a technological means to teach the different geometry subjects. 

2 Method 

When we want to analyze the effects of the educational materials or teaching meth-

ods in different schools, semesters, and classes, it will be easier to employ the quasi-

experimental research design. In this type of research design, the academic semesters 

are not organized based on a certain purpose; rather, they are taken in the research area 

as are, in their particular conditions. This is a beneficial and practical way when the 

sample selection is not made based on the equality of the groups (McMillan & Schu-

macher, 2006). Hence, this research was conducted in a quasi-experimental structure, 

unequal groups, and applied the pre-posttests. 

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Paper—Effect of Teaching Geometry by Slow-Motion Videos on the 8th Graders’ Achievement 

 

2.1 Population 

This research was conducted with the participation of 74 students of two different 

8th grades of a school located at the downtown of Zarqa City, during the second semes-

ter of the academic year 2018/2019. One of the two classes was assigned to be the 

experimental group and to use the slow-motion animation method (n=38). The other 

class was considered a control group, where the traditional teaching was dominant, 

which focuses on the teacher (n=36). The research was carried out in two different clas-

ses, with the same physical facilities and environmental conditions, over a three-week 

period (5 hours per week). 

2.2 Instruments 

The researcher measured the dependent variables, which are the academic achieve-

ment, and the students' views on teaching (animation technique). Meanwhile, the teach-

ing methods were the independent variables (teaching through the animation tech-

niques, and traditional teaching). 

To achieve the study purposes and answer its questions, the researcher constructed 

the following instruments: 

1) Assignments and activities were developed and constructed based on the slow-mo-

tion animation technology so that the concepts and theories the geometry unit pre-

sents in the form of a slow-motion video and explanatory audio recording, are rep-

resented. (The film includes an audio recording to explain the teaching content dur-

ing the film show. A part of the film was presented, then it was stopped, followed by 

an explanation or brief clarification of what was watched. Then the film is run till 

the end, with parts of it are sometimes replayed, once there is any ambiguity or lack 

of understanding. Sometimes, the film is stopped to posit questions to the students). 

• These developed assignments and activities, based on the slow-motion anima-

tions, were presented to a group of long experienced and distinguished math 

teachers in different schools, to review according to the set educational objec-

tives. 

• The amendments they proposed were simple, such as the inclusion of other 

concepts in the film that were not mentioned, time and speed of the show, too 

slow or too fast, giving priority of an idea over another during the film show, 

and clarity of the sound and picture. 

• The researcher further presented the assignments and activities to another ex-

pertise group in information technology to check them in terms of quality and 

technological aspects. Their comments and amendments were carried out as 

per their views to make the films clearer and of better quality. 

• In the animation group, the unit subjects were taught using animation tech-

niques. The first five minutes of the lesson were used to ask the students ques-

tions, to probe their prior knowledge about the subject. Then the lesson is 

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Paper—Effect of Teaching Geometry by Slow-Motion Videos on the 8th Graders’ Achievement 

 

taught through the slow-motion techniques, where the animations were pre-

sented through the mobile devices and data-show device over equal periods (5 

minutes each) (Fleer & Hoban, 2012; Turan, 2013). 

• Following the show, questions related to the subject were posited over 15 

minutes. Parts of the fully un-understood subjects were defined according to 

the answers, which were clarified anew using the animations. (See for instance, 

the links): https://youtu.be/u7kre9Z-Znk, https://youtu.be/kHVHN1RoGqI 

2) Achievement test that aims to measure the 8th graders' achievement in the stere-

ograph's unit, which was constructed based on the table of specifications. The test 

consisted of (36) items of the multiple-choice type, with one grade for each item. It 

was built according to the following procedures: 

• Analysis of the stereographs unit content by phrasing the educational objec-

tives of every lesson of the unit, which included seven lessons as follows: Net-

works, Size and surface area of the triangular prism, Size and surface area of 

the cylinder, Size and surface area of the cone, Size and surface area of the 

pyramid, Size and surface area of the ball, and Variation coefficient. 

• The objectives were categorized into three levels: knowledge, application, and 

inference. 

• The test items were written so that they include the objectives they were set 

for. 

• The test validity was verified by presenting it to a pool of reviewers, who were 

requested to provide their views and suggestions. The test items were amended 

in the light of their comments. The test was applied to an exploratory sample 

and the reviewers calculated the difficulty factors, which ranged between (0.30 

– 0.77), as well as discrimination coefficients, which were between (0.28 – 

0.79). The test reliability was also verified using the Cronbach Alpha coeffi-

cient, which was (0.85) that represents an educationally acceptable value. 

• The test was applied before the experiment to assure the parity between the 

experimental and control groups, and after the experiment to identify the stat-

ically significant differences between the two groups. 

3) The views of the students were measured using the student opinion scale (SOS), 

which Doymug, Simsek, and Bayrakecken (2004) used, and was applied to identify 

the students' views about the teaching method using the animation techniques. Fi-

nally, the test reliability was verified by applying the Cronbach Alpha coefficient, 

which amounted (0.88), an educationally acceptable value. 

2.3 Group parity 

To ensure the group parity, the researcher calculated the T-test value, which 

amounted (0.54), and the statistical significance was (0.59), which imply the nonexist-

ence of differences between the two groups in the application of the achievement pre-

test. This result shows that the students of both the control and experimental groups 

were similar in terms of achievement before applying the teaching methods. 

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Paper—Effect of Teaching Geometry by Slow-Motion Videos on the 8th Graders’ Achievement 

 

3 Results 

1. What is the effect of slow-motion animation use on the 8th graders' achievement in 

the geometry subject? 

The mean and standard deviation of the students' scores in the posttest were calcu-

lated, and then an independent sample T-test was carried out. The mean of the experi-

mental groups was 32.27 and the standard deviation was 1.54, while the mean and 

standard deviation of the control group were 21.19 and 1.41, respectively. On the other 

hand, the T value was 20.63 and p=0.00, which indicates that there were differences 

between the two groups in the achievement posttest. This result shows that the experi-

mental group students' achievement was better than the control group students. We fur-

ther found that the academic achievement levels of the students who attended the ge-

ometry lessons, based on the slow-motion animations (animation group), were higher 

than those who attended lessons through the traditional method (control group), as 

shown in Table (1). 

Table 1.  T-Test Results of the Posttest Achievement of the Independent Samples 

Group M SD T-Value Sig. 

Experimental 33.27 1.54 20.63 0.00 

Control 26.19 1.41 

2. What are the students' perspectives about the use of animations in geometry teach-

ing? 

This test was given to the experimental group by the end of the study to identify their 

views about the use of slow-motion animation technology. The percentages and means 

of the scores of the students' responses are displayed in Table (2). 

i. Was the use of the animation method during the lesson beneficial for you? 

The students' responses are shown in Table (2). 

Table 2.  Views about the Use of Animation Technology in the Lesson 

Score Response Percentage 

5 Very well 65 

4 Well 35 

3 Satisfactory - 

2 Not too well - 

1 Poorly - 

 

As illustrated in Table (2), the results show that the students adopted the use of slow-

motion animation. The data of the table shows that 100% of the students evaluate this 

technology as "very good", and "good". The results further show that the scores mean 

in this question was 4.60, which is higher than the midpoint (3), which, in turn, indicates 

the positive views of the students about the slow-motion animation technology. 

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Paper—Effect of Teaching Geometry by Slow-Motion Videos on the 8th Graders’ Achievement 

 

ii. What is your opinion about learning through slow-motion animations? The 

students' answers were as illustrated in Table (3). The figures of the table 

show that the percentages of the students range between 91-99% as per the 

point 4 and 5, respectively, and that the score mean of all the views was higher 

than the midpoint (3). 

Table 3.  Statistical Values of the Views about Question 2 "Learning Through Animations" 

Opinions Scores Opinions 

 1 2 3 4 5 x  

No information - 2 6 10 82 4.77 Information 

Difficult - - 3 10 87 4.84 Easy understandable 

Not Beneficial - - 1 5 94 4.93 Beneficial 

A poor instructive - - 7 13 80 4.73 Instructive 

Dull - 1 5 6 88 4.81 Stimulating 

Not enjoyable - - 5 18 77 4.72 Enjoyable 

Not creative - 2 10 18 70 4.56 Very creative 

X indicates score mean on a 5-point scale; other figure indicates percentage 

The results obtained from Table (3) show that the students found learning through 

slow-motion animation: beneficial, easily understandable, very creative, enjoyable, 

stimulating, and instructive. However, the results of this question are in line with those 

of Hoban and Nielsen, 2012; Dasdemir, Doymus, Simsek & Karacop, 2008. Therefore, 

we can conclude that the animation method was adopted by the students. 

4 Discussion and Conclusion 

The results showed that the use of slow-motion animations in teaching geometry has 

a positive effect on the students' achievement level. These results are in agreement with 

those of the studies of Gambari, Falode and Adegbenro, 2014; Kaplan and Ozlurk, 

2015, which aimed to verify the effectiveness of the computerized animations on the 

students' achievement and retaining what they learned on the long run. The results fur-

ther showed that the experimental group students outperformed those of the control 

group; and that the use of animation is an effective method in teaching different math 

subjects. The positive effects of using this method in geometry lessons were further 

supported by the students' views. In addition, these positive effects that are related to 

the animations techniques are in line with the results of Marbach-AD, Rotbain and 

Stavy (2008). 

The results of this study are also in line with those of Cho's (2012), who used ani-

mations in teaching his students. He found that the students' performance level was high 

in the tasks and activities they were exposed to recently and left a type of active partic-

ipation in the classroom. It is worth mentioning that many studies in the educational 

literature emphasized the effectiveness of the scientific animations of different kinds in 

improving the students' performance in mathematics in general (Wang, Chung & Tang, 

2014). 

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Paper—Effect of Teaching Geometry by Slow-Motion Videos on the 8th Graders’ Achievement 

 

This positive effect of the use of slow-motion animations in math teaching may be 

ascribed to that the information in these films is shown in an organized manner. They 

enable the individual further expand his/her knowledge with more efficiency. In this 

concern, the multiple representations, upon which the films are based in displaying 

knowledge (sound, picture, moving pictures, motion) form the wide difference between 

teaching using the traditional way and teaching using the slow-motion animations 

method. Interest in the way to represent the concepts the learner attempts to acquire 

through his/her practice, helps him/her develop his/her ability to process the infor-

mation obtained (Bruner, 1996, Takaya, 2008). These results were also in agreement 

with those of Salim & Tiawa (2015). 

In addition, the positive effect of the use of slow-motion animations could be further 

attributed to that these films may assist the student to stop at any point of time during 

the display to verify the information. They also create an effective discussion process 

with the other students to discuss the information displayed in the film and attempt 

deepening their understandings. In a similar context, Cho (2012) stated that the slow-

motion animations produced a positive classroom environment. Such an environment 

has a type of active participation followed by discussion with the other students. As a 

result, it helps students better utilize the time of the class more effectively and with 

more focus during the course of the lesson. It also provides the students an opportunity 

to depend on themselves in learning and developing their thinking (Gambari, Falode & 

Adegbenro, 2014; Kaplan & Ozturk, 2015; Wang, Chung & Yang, 2014). 

In this concern, Hoban & Nielsen, 2014; Hoban & Nielsen, 2012; Hoban, Loughran 

& Nielsen, 2011 stated that providing information and knowledge within these films 

offers every student an opportunity to learn and obtain the information anytime he/she 

so wishes. This is quite different from the traditional way in which the student needs to 

ask continuously to understand what he/she stopped bewildered beside. This is not al-

ways available due to the tight time of the lesson and the increasing numbers of students 

in the classroom, which render the teacher unable to answer all the students' questions, 

either due to the student's lack of attention, or inability to understand because the 

teacher did not take into account the different levels of the students. 

In addition, teaching geometry through slow-motion animations has its unique ad-

vantages, such as enhancing motivation, easy understanding, and contribution to the 

development of cognitive skills. in light of the results of the academic achievements 

and the students' views, the study recommends defining the duration of the animation 

shows. This could be obtained by taking the students' development characteristics into 

consideration, carrying out more studies on the use of the slow-motion animations in 

the primary education stages, and adding certain activities to the courses of the faculties 

of education, which assist in developing the skills of using the slow-motion techniques. 

5 References 

[1] Aktas, M. Bulut, M. & Yuksel, T. (2011). The Effect of Using Computer Animation and 

Activities about Teaching Patterns in Primary Mathematics. TOJET: The Turkish Online 

Journal of Educational Technology, 10(3), 273-277. 

64 http://www.i-jim.org



Paper—Effect of Teaching Geometry by Slow-Motion Videos on the 8th Graders’ Achievement 

 

[2] Berch, D. & Mazzocco M. (2007). Why is math so hard for some children? The Nature and 

Origins of Mathematical Learning Difficulties and Disabilities. Maryland: Paul H. Brookes 

Publishing Co. 

[3] Bruner, J. (1966). Toward a Theory of Instruction. New York, Norton & Company. INC. 

[4] Chahine, I. (2011). The Role of Translations between and within Representations on the 

Conceptual Understanding of Fraction Knowledge: A Tran Cultural Study. Journal of Math-

ematics Education. 4(1), 45-56. 

[5] Cho, H. (2012). The Use Cartoons as Teaching a Tool in Middle School Mathematics. Un-

published Doctor’s thesis. College of Art and Science, Columbia University: Columbia. 

[6] Daşdemir, I., Doymuş, K., Simşek, U.   &  Karaçöp, A., (2008). The effects of animation 
technique on teaching of acids and bases topics. Journal of Turkish science education. 5(2), 

60-69. 

[7] Doering, A., Veletsianos, G., Scharber, C. & Miller, C. (2009). Using the Technological, 

Pedagogical, and Content Knowledge Framework to design online Learning Environments 

and Professional Development. Journal of Educational computing Research, 41(3), 319-346. 

https://doi.org/10.2190/ec.41.3.d 

[8] Doymuş, K., Şimşek, Ü. & Bayrakçeken, S. (2004). The Effect of Cooperative Learning on 

Attitude and Academic Achievement in Science Lessons. Journal of Turkish Science Edu-

cation, 1(2), 103-115. 

[9] Ekici, F., Cakmak, N. & Ekici, E. (2014). Using Slow-motion as a Teaching Approach and 

its effect on biology achievements of pre-service science teachers. The Eurasia Proceedings 

of Educational & Social Sciences (EPESS), 1, 316-321. 

[10] Fleer, M. & Hoban, G. (2012). Using Slow motion for intentional teaching in early childhood 

centres: Possibilities and imaginings. Australasian Journal of Early Childhood. 37 (3), 61-

70. https://doi.org/10.1177/183693911203700309 

[11] Gambari, I., Falode, O. & Adegbenro, A. (2014). Effectiveness of computer animation and 

geometrical instructional model on mathematics achievement and retention among junior 

secondary school students. European Journal of Science and Mathematics Education, 2(2), 

127-146. 

[12] Harries, J. & Hofer, M. (2011). Technological Pedagogical Content Knowledge (TPACK) 

in Action: A Descriptive Study of Secondary Teachers’ Curriculum-Based, Technology-Re-

lated Instructional Planning. Journal of Research on Technology in Education, 43(3), 211-

229. https://doi.org/10.1080/15391523.2011.10782570 

[13] Hoban, G. & Nielsen, W. (2011). Engaging preservice primary teachers in creating multiple 

modal representations of science concepts with Slow motion. Research in Science Educa-

tion. 42, 1101–1119. https://doi.org/10.1007/s11165-011-9236-3 

[14] Hoban, G. & Nielsen, W. (2012): Learning Science through Creating a ‘Slow motion ’: A 

case study of preservice primary teachers, International Journal of Science Education, 

https://doi.org/10.1080/09500693.2012.670286 

[15] Hoban, G. & Nielsen, W. (2014). Creating a narrated stop-motion animation to explain sci-

ence: The affordances of "Slow motion" for generating discussion. Teaching and Teacher 

Education, 42, 68-78. https://doi.org/10.1016/j.tate.2014.04.007 

[16] Hoban, G. (2005). From Claymation to Slow motion: A teaching procedure to develop stu-

dents’ science understandings. Teaching Science: Australian Science Teachers’ Journal, 

51(2), 26–30. 

[17] Hoban, G. (2007). Using Slow motion to Engage Preservice Elementary Teachers in Under-

standing Science Content Knowledge. Contemporary Issues in Technology and Teacher Ed-

ucation, 7(2), 75-91. 

iJIM ‒ Vol. 14, No. 18, 2020 65

https://doi.org/10.2190/ec.41.3.d
https://doi.org/10.1177/183693911203700309
https://doi.org/10.1080/15391523.2011.10782570
https://doi.org/10.1007/s11165-011-9236-3
https://doi.org/10.1080/09500693.2012.670286
https://doi.org/10.1016/j.tate.2014.04.007


Paper—Effect of Teaching Geometry by Slow-Motion Videos on the 8th Graders’ Achievement 

 

[18] Hoban, G. (2009). Facilitating learner-generated animations with Slow motion. In L. Lock-

yer, S. Bennett, S. Agostino, & B. Harper (Eds.), Handbook of research on learning design 

and learning objects: Issues, applications and technologies (pp. 313–330). Hershey, PA: IGI 

Global. https://doi.org/10.4018/978-1-59904-861-1.ch015 
[19] Hoban, G., Ferry, B., Konza, D. & Vialle, W. (2007). Slow motion: exploring a new teaching 

approach in primary school classrooms. In J. Kiggins, L. K. Kervin & J. Mantei (Eds.), 

Quality in Teacher Education: Considering different perspectives and agendas. Proceedings 

of the 2007 Australian Teacher Education Association National Conference Wollongong: 

Australian Teacher Education Association. 

[20] Hoban, G., Loughran, J., & Nielsen, W. (2011). Slow motion: Preservice elementary teach-

ers representing science knowledge through creating multimodal digital animations. Journal 

of Research in Science Teaching, 48(9), 985–1009. https://doi.org/10.1002/tea.20436. 

[21] Kaplan, A. & Ozturk, M. (2015). The effect of Concept Cartoons to Academic Achievement 

in Instruction on the Topics of Divisibility. International Electronic Journal of Mathematics 

Education, 10(2), 67-76. http:// doi: 10.12973/mathedu.2015.105a 

[22] Keast, S., Cooper, R., Berry, A., Loughran, J. & Hoban, G. (2010). Slow motion as a peda-

gogical scaffold for improving science teaching and learning. Brunei International Journal 

of Science and Mathematics Education, 2 (1), 1-15. 

[23] Lesh, R., Cramer, K., Doerr, H., Post, T. & Zawojewski, J., (2003) Using a translation model 

for curriculum development and classroom instruction. Models and Modeling Perspectives 

on Mathematics Problem Solving, Learning, and Teaching. Retrieved from: 

http://www.cehd.umn.edu/rational number project/03_1.html, on 14/3/ 2019. 

[24] Marbach-Ad, G., Rotbain, Y. & Stavy, R. (2008). Using computer animation and illustration 

activities to improve high school students’ achievement in molecular genetics. Journal of 

Research in Science Teaching, 45: 273–292. https://doi.org/10.1002/tea.20222 

[25] McKnight, A., Hoban, G. & Nielsen, W. (2011), Using Slowmotion for animated storytell-

ing to represent non-Aboriginal pre-service teachers’ awareness of relatedness to country, 

Australasian Journal of Educational Technology, 27(1), 41-54. https://doi.org/10. 

14742/ajet.981 

[26] McMillan, J. & Schumacher, S. (2006). Research in education: Evidence-based inquiry (6th 

ed.). Boston, MA: Allyn and Bacon.  
[27] Niess, M., Ronau, R., Shafer, K., Driskell, S., Harper S., Johnston, C., Browning, C., Özgün-

Koca, S. & Kersaint, G. (2009). Mathematics teacher TPACK standards and development 

model. Contemporary Issues in Technology and Teacher Education, 9(1), 4-24. 

[28] Paige, K., Bentley, B., & Dobson, S. (2016). Slow motion: An Innovative Twenty-First Cen-

tury Teaching and Learning Tool for Science and Mathematics Pre-service Teachers. Aus-

tralian Journal of Teacher Education, 41(2), 1-15 http://doi.org/10.14221/ajte.2016 

v41n2.1 

[29] Salim. K. & Tiawa. H. (2015). The Student’s Perceptions of Learning Mathematics using 

Flash Animation Secondary School in Indonesia. Journal of Education and Practice, 34(6), 

76-80. 

[30] Takaya, K. (2008). Jerome Bruner’s Theory of Education: From Early Bruner to Later 

Bruner. Interchange, 39(1), 1-19. https://doi.org/10.1007/s10780-008-9039-2 

[31] Tambychik, T. & Meerah, T. (2010). Students' difficulties in mathematics problem-solving: 

What do they say? Procedia Social and Behavioral Sciences.8 (2010), 142-151. https://doi. 

org/10.1016/j.sbspro.2010.12.020. 

[32] Turan, B. (2013). The Opinions of Teachers on the Use of Cartoon Character in the Mathe-

matics Lesson. Journal of Social and Behavioral Sciences, 141(25), 1386-1391. 

https://doi.org/10.1016/j.sbspro.2014.05.239 

66 http://www.i-jim.org

https://doi.org/10.4018/978-1-59904-861-1.ch015
https://doi.org/10.1002/tea.20436
https://www.researchgate.net/journal/1306-3030_International_Electronic_Journal_of_Mathematics_Education
https://www.researchgate.net/journal/1306-3030_International_Electronic_Journal_of_Mathematics_Education
http://www.cehd.umn.edu/rational%20number%20project/03_1.html
https://doi.org/10.1002/tea.20222
https://doi.org/10.14742/ajet.981
https://doi.org/10.14742/ajet.981
http://doi.org/10.14221/ajte.2016v41n2.1
http://doi.org/10.14221/ajte.2016v41n2.1
https://doi.org/10.1007/s10780-008-9039-2
https://doi.org/10.1016/j.sbspro.2010.12.020
https://doi.org/10.1016/j.sbspro.2010.12.020
https://doi.org/10.1016/j.sbspro.2014.05.239


Paper—Effect of Teaching Geometry by Slow-Motion Videos on the 8th Graders’ Achievement 

 

[33] Wang, Y., Chung, J. & Yang, L. (2014). Using Clickers to Enhance Student Learning in 

Mathematics. International Education Studies, 7(10), 1-13 https://doi.org/10.5539/ies. 

v7n10p1 

6 Authors 

Mohammed Al-khateeb is an associate professor at the Hashemite University in 

Jordan specializing in mathematics teaching methods. He is interested in research in 

mathematics education and how to employ technology in teaching mathematics. Email: 

mkm7879@hu.edu.jo 

Ahmed Alduwairi is a professor at Albayt university in Jordan specializing in math-

ematics teaching methods. He is interested in research in mathematics education and 

how to employ technology in teaching mathematics. Email: Drduwairi@aabu.edu.jo 

Article submitted 2020-01-02. Resubmitted 2020-05-03. Final acceptance 2020-05-12. Final version pub-
lished as submitted by the authors. 

iJIM ‒ Vol. 14, No. 18, 2020 67

https://doi.org/10.5539/ies.v7n10p1
https://doi.org/10.5539/ies.v7n10p1
mkm7879@hu.edu.jo
mailto:Drduwairi@aabu.edu.jo