ORIGINAL RESEARCH ARTICLE
Omar M. Mahasneh*
Department of Basic and Applied Science, Faculty of Shobak University College, AL-Balqa Applied University, Al-salt, Jordan
Received 24 August 2019; Revised 12 November 2019; Accepted 30 September 2020; Published: 24 November 2020
There have been efforts to investigate the effectiveness of the flipped learning strategy in the development of scientific research skills (SRS) in the procedural research course among higher education diploma students. However, studies examining the effectiveness of the flipped learning strategy in the development of SRS are, thus far, rare. This study adopted a quasi-experimental design, with two types of teaching methods. One research group was assigned to the flipped learning teaching method (n = 30) and the other to the conventional teaching method (n = 30). A multiple-choice SRS test was developed and used. The results showed that the flipped learning teaching method was more effective than the conventional teaching method, in gauging students’ SRS.
Keywords: flipped learning strategy; Shoubak University College; scientific research skills; procedural research course
*Corresponding author. Email: Omar_mahasne@bau.edu.jo
Research in Learning Technology 2020. © 2020 O.M. Mahasneh. Research in Learning Technology is the journal of the Association for Learning Technology (ALT), a UK-based professional and scholarly society and membership organisation. ALT is registered charity number 1063519. http://www.alt.ac.uk/. This is an Open Access article distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), allowing third parties to copy and redistribute the material in any medium or format and to remix, transform, and build upon the material for any purpose, even commercially, provided the original work is properly cited and states its license.
Citation: Research in Learning Technology 2020, 28: 2327 - http://dx.doi.org/10.25304/rlt.v28.2327
Since the first decade of the 21 century, the educational term ‘Flipped Learning’ has become a key topic in the educational and social sciences, as mentioned by many researchers in the domains (Thaichay and Sitthitikul 2016; Wei & Lin 2016; Yang 2017; Yuan and Chen 2018; Zainuddin & Halili 2016). From the theoretical literature, flipped learning emerges as a pedagogical approach, in which direct instruction moves from the group learning space to the individual learning space, and the resulting group space is transformed into a dynamic, interactive learning environment, where the educator guides students as they apply concepts and engage creatively with the subject matter (Salem and ALwan 2018; Şanal 2016; Saunders 2014; Sedo & Kber 2018). Flipped learning is a strategy that makes the learner enjoy studies successfully. Zainuddin and Halili (2016) suggested flipped learning being made part of curriculum of school and universities. The current study is aimed to investige the effectiveness of the flipped learning strategy in the development of scientific research skills (SRS) in the procedural research course among higher education diploma students.
Modern technology has helped to transform the traditional lecture style, which is limited to teaching within the classroom, and by relying on the method of lecture and teaching by the teacher. With scientific and technological progress, modern educational strategies seek to reshape the educational process and to change the traditional role of the school and home, where the learner takes a more active and responsible role in the process of learning. Flipped learning is one of the strategies envisaged in this process.
Flipped learning is one of the integrated learning strategies, which is an educational system that takes advantage of all the possibilities and technological means available by combining more than one learning method, whether electronic or conventional, to provide a new quality of learning that suits the characteristics and needs of the learners on the one hand and the nature of the course and the educational goals we try to achieve on the other hand (Yu, Chang and Wu 2015; Yu and Wu 2012).
Johnson et al. (2014) confirm that flipped learning is a type of integrated learning, which combines the activation of technology in learning without forgetting the role of interaction between the teacher and the learner, the recognition of technology and its tools as ideal for effective learning. To bring about fundamental changes in the educational context and educational institutions, the flipped learning strategy is working to enrich the learning process and achieve learning outcomes, positive at the cognitive level of increased achievement, skills acquisition, an emotional liking of the subject matter and positive interaction within the classroom between the teacher and the learners, or among the learners.
From a study of the theoretical literature and previous studies, Figure 1 furnishes a comparison between traditional learning and flipped learning (AdedoJa 2016; Altweigy 2017; Anderson and Krathwohl 2001; Başal 2012; Bergmann 2014; Bergmann and Sams 2012, 2014, 2015; Bill 2012; Bonk and Graham 2007; Bram 2013; Brame 2013; Bsharat 2017; Chang 2016; Mahasneh and Farajat 2015; Mahasneh and Murad 2014).
Figure 1. Comparison of traditional learning and flipped learning.
Many researchers (Drake, Micaela and Robin 2016; Durak 2015, 2016; Fiorella and Mayer 2013; Flipped Learning Network 2014; Gecu and Satici 2012; Gerstein 2012) have confirmed the advantages of flipped learning. Flipped learning is able to constantly adapt itself to students’ needs; it is mixed with fun and vitality with a little explanation inside the classroom, and a lot of collaborative learning and discussions and educational projects; it helps underachievers by arranging help from the teacher who walks around the students, thorough watching educational videos at home, making the teacher focus on students who need more time to learn and in guiding them to improve their performance. In adhering to the requirements of the digital age, flexibility and effectiveness, flipped learning increases interaction between teacher and student and helps students of all levels to excel, especially those with special needs. Flipped learning helps in classroom management, transparency and overcoming the shortage of qualified teachers as well as teacher absenteeism. It ensures good investment of lesson time, taking into account the individual differences among students by repeating the lesson more than once through the video and strengthening the relationship between the teacher and students. Flipped learning encourages the optimal use of modern techniques in the field of education. The student becomes an information-searcher rather than a mere passive recipient. It also enhances critical thinking skills, self-learning, experience building, and communication and collaboration skills among students.
The researcher conducted the procedures described in Figure 2.
Figure 2. Teaching procedures by flipped learning.
The researcher developed a set of instructions for students in the experimental group, as shown in Figure 3.
Figure 3. Instructions for students.
The researcher, after studying the theoretical literature and previous studies, did not find studies on the subject of determining the effectiveness of the flipped learning strategy in the development of SRS. Studies were mostly focused on the effectiveness of the flipped learning strategy in the development of group variable. Bsharat (2017) investigated the effect of using the flipped learning strategy on tenth-grade students’ achievement and their mathematical self-concept at Jericho Governorate. It was applied as a quasi-experimental approach on a sample of 43 tenth graders at Al-jeftlek secondary co-education school. The researcher used two tools in the study. A post-test measures the achievement of the students after the completion of teaching of the special geometry unit (C) and (A) scale of mathematical self-concept in the pre- and post-phases of using flipped learning strategy. The results of the study were statistically significant at α = 0.05, based on the achievement of the post-test, and the scale of the mathematical self-concept of the tenth-grade student was in favour of the treatment group who used the flipped learning strategy to learn the special geometry unit.
Qtash (2019) studied the effect of using the flipped learning strategy on the achievement and retention of second-grade students in mathematics skills. To achieve this goal, the study used a quasi-experimental design. The sample of the study consisted of 40 male and female students, selected purposively from a government school in Amman. The sample was distributed into two intact groups: an experimental group consisting of 20 male and female students was taught by the flipped learning instructional strategy and a control group consisting of 20 male and female students was taught by the traditional method. The findings of the study revealed that there were significant differences for the experimental group that was taught through the flipped learning instructional strategy in the achievement test. There were also statistical differences between the experimental group who was taught through the flipped learning instructional strategy in the achievement and cognitive retention of mathematical skills.
Salem and Alwan (2018) investigated the effectiveness of the flipped learning strategy in pattern-making and grading of women’s clothing, using Gemini CAD System. The sample consisted of 30 female students. The findings of the study revealed that there were significant differences for the experimental group who was taught through the flipped learning instructional strategy in the achievement test.
Qstah (2016) studied the impact of using the flipped learning strategy on concept development and reflective thinking in biology, among female tenth graders, adopting the descriptive analytical approach and the experimental approach. Study tool, content analysis tool, a scientific concepts test and a reflective thinking test were employed. The sample consisted of 80 female students in the tenth grade. As shown in the results, there are statistically significant differences at the significance level (0.05 ≥ α) between the mean scores of the control group and the experimental group in the science concepts test, in favour of the experimental group. There are statistically significant differences at the significance level (0.05 ≥ α) between the mean scores of the control group and the experimental group in the reflective thinking test, in favour of the experimental group.
Sedo and Kber (2018) aimed at identifying the influence of using flipped strategy on the achievement of Faculty of Education in Gadarif University. The researchers adopted both descriptive study and experimental methods; these two methods were most appropriate for this study. The tools used in the study were achievement test and attitude test. The results of these analyses were used to discuss the hypotheses of the study. The main findings were (1) there are statistical differences in educational achievement, showing the experimental group benefiting, (2) students taught through the flipped strategy were more effective and positive than those taught by traditional method and (3) there are strong and positive attitudes among fifth class students towards use of flipped strategy in teaching lessons.
Overmyer (2014) studied the effect of the flipped classroom model on college algebra students’ achievement. His findings show that though there was no statistically significant difference in the scores of students in the two groups, students in the flipped sections did score slightly better than those in the traditional sections.
Yuan and Chen (2018) investigated the effects of flipped learning, student question generation and instant response technologies on students’ learning motivation, attitudes and engagement. By a structural equation modelling, the results showed that the constructs of flipped learning and student question generation have a positive impact on the students’ learning motivation, attitudes and engagement.
All the earlier studies focused on the effect of flipped learning on some variables (achievement). The present study differs from previous studies in that it is the only study that investigates the effectiveness of the flipped learning strategy in the development of SRS.
The aim of this study is to contribute to the knowledge of the effectiveness of using the flipped learning strategy in the development of SRS (procedural research) among higher education diploma students. The research was conducted on 60 students comprising experimental and control groups. This study is one of the rare studies in this domain, as it distinguished the structure of the instrument for SRS test, to measure the effectiveness of using the flipped learning strategy in the development of SRS among higher education diploma students.
In line with this research intent, only main hypotheses were identified:
H0: there are no statistically significant differences in α = 0.05 between the average achievement in the testing of SRS of the students between the experimental and the control groups.
The study attempted to answer the following questions:
First question: What are the SRS to be developed by students in the course of procedural research?
Second question: Is there a statistically significant (α = 0.05) difference between the average scores of the students of the experimental group and those of the control group in the test of SRS?
The study adopted a quasi-experimental design.
In this study, the effectiveness of using the flipped learning strategy in the development of SRS on the course (procedural research) among higher education diploma students was investigated.
The individuals for this study consisted of 60 students. Table 1 shows their characteristics.
Group | Frequency |
Experimental | 30 |
Control | 30 |
Total | 60 |
The researcher first made an arrangement to work with the Dean of Shoubak University College, structured the instruments and verified their validity and reliability.
In this study, the researcher’s main focus was to investigate the effectiveness of using the flipped learning strategy in the development of SRS on the course (procedural research) among higher education diploma students. Theoretical literature and previous studies related to the subject of research were studied to structure the study instrument SRS. Appendix 1 shows the sample instruments used finally in the study.
The skills of scientific research in the course of procedural research were determined through theoretical literature, previous studies and course content. The list of SRS consists of 30 skills divided into five domains, as shown in Table 2.
To determine the effectiveness of using the flipped learning strategy in the development of SRS on the course (procedural research) among higher education diploma students, they were measured through the SRS test, consisting of 30 multiple-choice questions, yielding a total score of 30.
The skills of scientific research in the course of procedural research were determined through theoretical literature, previous studies and course content, and then checked with experts for language, clarity, relevance and comprehensiveness of the content. The items were rated as follows: 4 – Very relevant, 3 – Quite relevant, 2 – Somewhat relevant and 1 – Irrelevant. The researcher then puts the items into two groups: categories 1 and 2 in one group and 3 and 4 in the other. The researcher then calculated the Content Validity Index (CVI) using the following formula:
CVI = items rated as very relevant and relevant (3 and 4)/total number of items
For the instrument to be valid, the CVI had to be within the accepted statistical range of 0.7–1. Computed CVI for the instrument was found to be 0.98.
After the final preparation of the test, the researcher applied the test to a sample of 10 students, with the aim of finding the difficulty and discrimination coefficients for test paragraph, the calculation of the validity and reliability of the test and the time required for the test to be applied. The validity of internal consistency was verified, by finding the correlation coefficients (Pearson) between the score of each paragraph and the total score of the test, using the statistical program (SPSS), as shown in Table 2.
Table 2 shows that all the test paragraphs achieved significant correlation with all score of the test at 0.05, demonstrating the test’s internal consistency.
To verify the constructional validity, the researcher found the correlation of the domains of the test of the skills of scientific research with the total score of the test, as shown in Table 3. Table 3 shows that the domains of SRS that constitute the test achieved correlation with the total score of the test. Correlation range was 0.887–0.923, all of which are statistically significant at a level of significance 0.05.
Verification of the difficulty and discrimination coefficients for test paragraph are shown in Table 4. Table 4 shows that the degree of difficulty of the test was between 0.42 and 0.59, and that the degree of discrimination between the tests was between 0.71 and 0.53, indicating that all test intervals fall within the acceptable level of difficulty and discrimination.
The researcher used the Cronbach’s alpha method to measure the reliability of the test as a first method reliability; the coefficient of test reliability was found using the Cronbach’s alpha, as shown in Table 5. Table 5 shows that the value of the total reliability coefficients is 0.898, which is its high value; this indicates that the test has a high degree of reliability.
With the aid of SPSS version 16.0,the researcher used mean, standard deviation and analysis of the variance(ANCOVA) to compare the average scores of the students of the experimental group and the students of the control group in the SRS test.
To answer this question, the skills of scientific research in the course of procedural research were determined through theoretical literature, previous studies and course content. Table 6 shows this.
In summary, according to Table 6, the list of SRS consists of 30 items divided into five domains. The researcher confirms that all the SRS were included in the course of procedural research.
To answer this question, the following zero hypothesis was formulated:
H0: there is no statistically significant difference in α = 0.05 between the average achievement in the testing of SRS of the students between the experimental group and the control group.
To test this hypothesis, mean, standard deviation and ANCOVA were used to compare the average scores of the students of the experimental group and the students of the control group in the test of SRS, as shown in Tables 7–10. The pretest was applied to the study subjects to ensure the equivalence of the study groups, as shown in Table 7.
Tests of between-subject effects | ||||||
Dependent variable: post-test | ||||||
Source | Type III sum of squares | df | Mean square | F | Sig. | η2 |
Corrected model | 2346.850a | 2 | 1173.425 | 302.193 | 0.000 | |
Intercept | 1355.448 | 1 | 1355.448 | 349.069 | 0.000 | |
Pretest | 3.100 | 1b | 3.100 | 0.798 | 0.375 | 0.12 |
Method teaching | 2118.059 | 1 | 2118.059 | 545.465 | 0.000 | 0.913 |
Error | 221.333 | 57 | 3.883 | |||
Total | 23963.000 | 60 | ||||
Corrected total | 2568.183 | 59 | ||||
aR squared = 0.914 (adjusted R squared = 0.911) bBold value to show the value of the statistical significance |
Tools | Small | Moderate | High | Very high |
d | 0.2 | 0.5 | 0.8 | 1.10 |
η2 | 0.01 | 0.06 | 0.14 | 0.20 |
Table 7 shows that there is an equivalence between the study groups, with the mean of the experimental group (M = 3.57) and control group (M = 0.92).
The mean and standard deviations of the students’ marks were calculated on the testing of post-SRS according to the variable of the teaching method.
Table 8 shows an apparent difference in the mean of student performance (course of procedural research) to test the skills of post-scientific research between the experimental and control groups. The experimental group appears to have benefited with the mean of 25.13 and that of the control group 12.63. To illustrate the significance of the differences in the statistical averages of student scores at the level of α = 0.05, the ANCOVA of the individual marks was used to test the skills of post-SRS according to the group variable and the results of Table 9.
Table 9 shows statistically significant differences at the level of α = 0.05 for the effect of teaching method. Considering the value of f calculated (545.465) and the level of significance (0.000), this value is less than the level of significance (0.05), and there is a difference of statistical significance between the control and experimental groups. The ETA squared of the teaching method is 0.931. It is clear that the effect of the use of the flipped learning strategy on the acquisition of SRS is very high, indicating the importance of this strategy in acquiring SRS teaching, compared with the traditional method of teaching.
Table 10 shows that the values of the η2 field coefficient and the magnitude of the effect are significant, indicating that the magnitude of the effect of using the flipped learning strategy in the development of SRS in the course of procedural research is very high.
In summary, for research question 2, the results showed that the mean in the traditional method scores was lower than the mean using flipped learning method in acquiring SRS. The effect size of the treatment was calculated using Cohen’s d and found to be d = 1.951. This indicated that the flipped classroom treatment had a ‘very high’ effect, using Cohen’s terminology, on the common final exam scores of the treatment group (Cohen 1988).
The aim of this study was to investigate the effectiveness of the flipped learning strategy in the development of SRS in the procedural research course among higher education diploma students. The results indicated that the flipped classroom treatment had a ‘high’ effect, implying that there are differences of statistical significance between the average scores of students in the experimental group and control group in the test skills of scientific research, to the benefit of the experimental group. The researcher emphasises that the skills of scientific research are prerequisites for students of the course of procedural research, and that the reverse learning strategy contributed to a great extent in the development of SRS (like identifying the study problem and its theoretical background, theoretical literature and previous studies, method and procedures, results and discussion, other research skills). The researcher justified this with the following:
In this study, I strove to explore the effectiveness of the flipped learning strategy in the development of SRS in the procedural research course among higher education diploma students. I conducted the study under normal conditions in order to produce accurate results.
This study has brought important, but in some ways limited, knowledge. One advantage is that it is part of a wider project, in which we have additional sources of data to analyse. Not all the data that we collected from this sample of students have been utilised in this study. In addition, the present quantitative study will be followed by a study on the construction of implementing training programs to train the faculty members on how to use the flipped education strategy.
This study was carried out by the researcher without any funding.
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