Computer Applications Technology Teaching: A Case of Supporting Secondary School Curriculum Imperatives
- Makena, Bulelwa, Yengwayo, Zameka Primrose
- Authors: Makena, Bulelwa , Yengwayo, Zameka Primrose
- Date: 2023
- Subjects: Computer skills , Digital tools , Computer , Online applications , Technology
- Language: English
- Type: Article
- Identifier: http://hdl.handle.net/11260/14216 , vital:79155 , DOI: https://doi.org/10.31435/rsglobal_ijitss/30092023/8028
- Description: The purpose of this study was to determine whether Computer Applications Technology secondary school teachers receive necessary support. Qualitative approach was chosen because it incites the most important meaning from participants and best suited for small samples. As case study embedded this investigation. A case study was used for this qualitative paper with an aim to investigate whether Computer Applications Technology teaching was supported to enhance secondary school curriculum imperatives. Three participants were selected purposively from a rurally located Eastern Cape Education District. To collect data, semi-structured interviews were used. Data were analysed thematically. Findings indicated that teachers do not receive necessary support on technology use, this caused by insufficient school funds to render trainings towards upskilling human resource for expected content knowledge. The paper recommends that school authorities need to support teachers and learners as CAT is one of the vital subjects underpinning school curriculum. In conclusion, school authorities is obliged to render support towards developed computer literacy skills.
- Full Text:
- Date Issued: 2023
- Authors: Makena, Bulelwa , Yengwayo, Zameka Primrose
- Date: 2023
- Subjects: Computer skills , Digital tools , Computer , Online applications , Technology
- Language: English
- Type: Article
- Identifier: http://hdl.handle.net/11260/14216 , vital:79155 , DOI: https://doi.org/10.31435/rsglobal_ijitss/30092023/8028
- Description: The purpose of this study was to determine whether Computer Applications Technology secondary school teachers receive necessary support. Qualitative approach was chosen because it incites the most important meaning from participants and best suited for small samples. As case study embedded this investigation. A case study was used for this qualitative paper with an aim to investigate whether Computer Applications Technology teaching was supported to enhance secondary school curriculum imperatives. Three participants were selected purposively from a rurally located Eastern Cape Education District. To collect data, semi-structured interviews were used. Data were analysed thematically. Findings indicated that teachers do not receive necessary support on technology use, this caused by insufficient school funds to render trainings towards upskilling human resource for expected content knowledge. The paper recommends that school authorities need to support teachers and learners as CAT is one of the vital subjects underpinning school curriculum. In conclusion, school authorities is obliged to render support towards developed computer literacy skills.
- Full Text:
- Date Issued: 2023
Developing metacognition through the use of Technology in self-organised learning environments in grade 11 Physical Sciences
- Authors: Tsamago, Hodi Elias
- Date: 2022-06
- Subjects: Metacognition , Technology
- Language: English
- Type: Doctoral's theses , Thesis
- Identifier: http://hdl.handle.net/10948/59910 , vital:62687
- Description: The study was carried out to investigate the effect of the use of technology in self-organised learning environments (SOLEs) (in Physical Sciences classrooms) on learners’ metacognitive skills. The study contributes by identifying a technology-enhanced pedagogy that can effectively equip learners with metacognitive skills, which many studies have reported as having an effect on Physical Sciences learners’ conceptual understanding. The study followed an experimental (control group quasi-experimental) methods design, in which both qualitative and quantitative data were collected and analysed. A multistep stratified sampling method (which caters for both quantitative and qualitative facets) was employed to choose four schools (two rural and two urban) to participate in the study. These schools were randomly chosen from the population of all schools offering Physical Sciences in Grade 11 in the Capricorn District of Limpopo Province, South Africa were assigned to urban experimental group and rural experimental group (UEG and REG) and urban control group and rural control group (UCG and RCG) using geographical demographics. The participants were selected using both simple random sampling (for quantitative methods) and purposive sampling (for qualitative methods). The experimental groups were taught by the researcher using self-organised learning environments (SOLEs) pedagogy, while control groups were taught (also by the researcher of the study) using a traditional chalk-and-talk approach. A Physical Sciences concepts pre-/post-test and the Metacognitive Self-Assessment Scale (MSAS) questionnaire were used to glean the quantitative data, while focus group interviews (FGIs) were used to obtain the qualitative data. The analysis of the quantitative data employed both descriptive (mean, standard deviation and graphs) and inferential (both parametric t-test and non-parametric Kruskal-Wallis and Wilcoxon signed-rank tests) statistics computed using the SPSS package version 22, while qualitative data were analysed thematically using coding techniques (applied on a sentence-by-sentence basis) after the transcription of the recorded FGIs. The study found that SOLEs pedagogy improves learners’ metacognitive skills, leading to better Physical Sciences conceptual understanding. In addition, the results indicate that all v aspects of metacognitive skills improved in experimental groups; however, certain aspects exhibited outstanding improvement such as “Respect shown to myself”; “Respect shown to others”; “Respect shown for empathy towards others” and “Respect shown towards problem solving”. Furthermore, the results of the FGIs revealed that a plausible explanation for the ability of SOLEs pedagogy to enhance metacognitive skills lies in its effortlessness to enable learners to link their classroom experiences to real-life experiences; simulate practical work; adapt to collaborative learning; use multiple channels for receiving information; and reducing learners’ reliance on the teacher. Hence, this study recommends the implementation of SOLEs pedagogy in the Physical Sciences classroom to improve learners’ metacognitive skills and conceptual understanding. However, the study had limitations, some of which included the sample size (which has an effect on the degree of generalisability of the research findings) and the period during which SOLEs pedagogy was implemented which might not have been long enough to exhaust its effect on metacognitive skills. Accordingly, further studies employing a longitudinal study design with a sample size bigger than 350 participants would be useful in understanding the effects of SOLEs pedagogy on metacognitive skills and improving the generalisability of research findings. , Thesis (PHD) -- Faculty of Education, 2022
- Full Text:
- Date Issued: 2022-06
- Authors: Tsamago, Hodi Elias
- Date: 2022-06
- Subjects: Metacognition , Technology
- Language: English
- Type: Doctoral's theses , Thesis
- Identifier: http://hdl.handle.net/10948/59910 , vital:62687
- Description: The study was carried out to investigate the effect of the use of technology in self-organised learning environments (SOLEs) (in Physical Sciences classrooms) on learners’ metacognitive skills. The study contributes by identifying a technology-enhanced pedagogy that can effectively equip learners with metacognitive skills, which many studies have reported as having an effect on Physical Sciences learners’ conceptual understanding. The study followed an experimental (control group quasi-experimental) methods design, in which both qualitative and quantitative data were collected and analysed. A multistep stratified sampling method (which caters for both quantitative and qualitative facets) was employed to choose four schools (two rural and two urban) to participate in the study. These schools were randomly chosen from the population of all schools offering Physical Sciences in Grade 11 in the Capricorn District of Limpopo Province, South Africa were assigned to urban experimental group and rural experimental group (UEG and REG) and urban control group and rural control group (UCG and RCG) using geographical demographics. The participants were selected using both simple random sampling (for quantitative methods) and purposive sampling (for qualitative methods). The experimental groups were taught by the researcher using self-organised learning environments (SOLEs) pedagogy, while control groups were taught (also by the researcher of the study) using a traditional chalk-and-talk approach. A Physical Sciences concepts pre-/post-test and the Metacognitive Self-Assessment Scale (MSAS) questionnaire were used to glean the quantitative data, while focus group interviews (FGIs) were used to obtain the qualitative data. The analysis of the quantitative data employed both descriptive (mean, standard deviation and graphs) and inferential (both parametric t-test and non-parametric Kruskal-Wallis and Wilcoxon signed-rank tests) statistics computed using the SPSS package version 22, while qualitative data were analysed thematically using coding techniques (applied on a sentence-by-sentence basis) after the transcription of the recorded FGIs. The study found that SOLEs pedagogy improves learners’ metacognitive skills, leading to better Physical Sciences conceptual understanding. In addition, the results indicate that all v aspects of metacognitive skills improved in experimental groups; however, certain aspects exhibited outstanding improvement such as “Respect shown to myself”; “Respect shown to others”; “Respect shown for empathy towards others” and “Respect shown towards problem solving”. Furthermore, the results of the FGIs revealed that a plausible explanation for the ability of SOLEs pedagogy to enhance metacognitive skills lies in its effortlessness to enable learners to link their classroom experiences to real-life experiences; simulate practical work; adapt to collaborative learning; use multiple channels for receiving information; and reducing learners’ reliance on the teacher. Hence, this study recommends the implementation of SOLEs pedagogy in the Physical Sciences classroom to improve learners’ metacognitive skills and conceptual understanding. However, the study had limitations, some of which included the sample size (which has an effect on the degree of generalisability of the research findings) and the period during which SOLEs pedagogy was implemented which might not have been long enough to exhaust its effect on metacognitive skills. Accordingly, further studies employing a longitudinal study design with a sample size bigger than 350 participants would be useful in understanding the effects of SOLEs pedagogy on metacognitive skills and improving the generalisability of research findings. , Thesis (PHD) -- Faculty of Education, 2022
- Full Text:
- Date Issued: 2022-06
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