In mathematics education, students’ beliefs that could take many different forms like students' beliefs about mathematics learning mathematics teaching; and about themselves play a significant role in their learning and achievement. In particular, self-belief (SB) that is students’ evaluation and judgment about themselves in learning solid geometry, which encompassing control belief (CB), goal orientation (GO), self-concept (SC), self-efficacy (SE), and task value (TV), is critical to their success in learning solid geometry. Addressing these SB dimensions can substantially improve students' learning outcomes in solid geometry. Innovative, student-centered instructional approaches like GIBI, especially when combined with variation theory, offer a potential solution for overcoming Ethiopian secondary schools’ educational challenges by promoting active learning and providing varied examples to enhance engagement and achievement. However, there is a lack of research on the effectiveness of this combined approach in Ethiopia context. This study aims to fill this gap by investigating the effects of variation theory integrated GIBI on grade ten students' SB in learning solid geometry in Ethiopia. Employing a quasi-experimental with non-equivalent control group pretest-posttest design, 102 students from three public secondary schools in Debre Tabor city, Amhara region were randomly assigned into three groups: Experimental Group 1 (EG1) received GIBI with variation theory, Experimental Group 2 (EG2) received GIBI without variation theory, and the Control Group (CG) received traditional teaching methods. A SB questionnaire was used to measure students' CB, GO, SC, SE, and TV before and after the intervention. The results revealed significant improvements in the SB dimensions among students in EG1 compared to those in EG2 and CG. Specifically, EG1 students showed higher post-test scores in CB (F (2,99)=40.29, p=0.000, η²=0.449); GO (F (2,99)=3.43, p=0.036, η²=0.065); SC (F (2,99)=32.09, p=0.000, η²=0.393); SE (F (2,99)=24.02, p=0.000, η²=0.327); and TV (F (2,99)=5.35, p=0.000, η²=0.097). Tukey post hoc tests indicated that EG1 students' scores were significantly higher than those of the CG in CB and GO, and higher than EG2 and CG in SC, SE, and TV. These findings suggest that the integration of variation theory with GIBI effectively enhances students' SB in learning solid geometry, thereby addressing the educational challenges faced by Ethiopian students. The study recommends adopting this instructional approach more widely to improve student outcomes in mathematics.
Published in | International Journal of Secondary Education (Volume 12, Issue 3) |
DOI | 10.11648/j.ijsedu.20241203.12 |
Page(s) | 56-67 |
Creative Commons |
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/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
Copyright |
Copyright © The Author(s), 2024. Published by Science Publishing Group |
Guided Inquiry-Based Instruction, Self-Belief, Solid Geometry, Variation Theory
Study Groups | Intervention | ||
---|---|---|---|
EG1 | Pre-Test | GIBI plus Variation Theory | Post-Test |
EG2 | Pre-Test | GIBI | Post-Test |
CG | Pre-Test | Traditional Teaching Methods | Post-Test |
SB Dimensions | Cronbach Alpha |
---|---|
Control Belief (CB) | 0.704 |
Goal Orientation (GO) | 0.752 |
Self-Concept (SC) | 0.786 |
Self-Efficacy (SE) | 0.676 |
Task Value (TV) | 0.777 |
Sum of Squares | df | Mean Square | F | Sig. | |
---|---|---|---|---|---|
Between Groups | 1112.230 | 2 | 556.115 | 1.982 | .143 |
Within Groups | 28344.530 | 101 | 280.639 | ||
Total | 29456.760 | 103 |
Sum of Squares | df | Mean Square | F | Sig. | |
---|---|---|---|---|---|
Between Groups | 9422.118 | 2 | 4711.059 | 27.269 | .000 |
Within Groups | 17103.343 | 99 | 172.761 | ||
Total | 26525.461 | 101 |
(I) Study Groups | (J) Study Groups | Mean Difference (I-J) | Std. Error | Sig. | 95% Confidence Interval | ||
---|---|---|---|---|---|---|---|
Lower Bound | Upper Bound | ||||||
Tukey HSD | EG1 | EG2 | 16.001 | 3.163 | .000 | 8.48 | 23.53 |
CG | 24.004 | 3.312 | .000 | 16.12 | 31.89 | ||
EG2 | EG1 | -16.001 | 3.163 | .000 | -23.53 | -8.48 | |
CG | 8.003 | 3.135 | .032 | .54 | 15.46 | ||
CG | EG1 | -24.004 | 3.312 | .000 | -31.89 | -16.12 | |
EG2 | -8.003 | 3.135 | .032 | -15.46 | -.54 |
N | Mean | Std. Deviation | Std. Error | 95% Confidence Interval for Mean | ||
---|---|---|---|---|---|---|
Lower Bound | Upper Bound | |||||
EG1 | 31 | 132.13 | 10.356 | 1.860 | 128.33 | 135.93 |
EG2 | 39 | 116.13 | 15.143 | 2.425 | 111.22 | 121.04 |
CG | 32 | 108.13 | 12.916 | 2.283 | 103.47 | 112.78 |
Total | 102 | 118.48 | 16.206 | 1.605 | 115.30 | 121.66 |
Source | Dependent Variable | Type III Sum of Squares | df | Mean Square | F | Sig. | Partial Eta Squared |
---|---|---|---|---|---|---|---|
Groups | CBPreTS | 5.080 | 2 | 2.540 | .370 | .692 | .007 |
GOPreTS | 149.699 | 2 | 74.850 | 2.919 | .059 | .055 | |
SCPreTS | 174.711 | 2 | 87.355 | 4.359 | .051 | .079 | |
SEPreTS | 20.999 | 2 | 10.500 | 1.333 | .268 | .026 | |
TVPreTS | 61.781 | 2 | 30.891 | .938 | .395 | .018 | |
Error | CBPreTS | 693.833 | 101 | 6.870 | |||
GOPreTS | 2589.647 | 101 | 25.640 | ||||
SCPreTS | 2024.126 | 101 | 20.041 | ||||
SEPreTS | 795.761 | 101 | 7.879 | ||||
TVPreTS | 3325.209 | 101 | 32.923 | ||||
Total | CBPreTS | 21167.000 | 104 | ||||
GOPreTS | 82604.000 | 104 | |||||
SCPreTS | 42175.000 | 104 | |||||
SEPreTS | 13291.000 | 104 | |||||
TVPreTS | 129043.000 | 104 |
Source | Dependent Variable | Type III Sum of Squares | df | Mean Square | F | Sig. | Partial Eta Squared |
---|---|---|---|---|---|---|---|
Corrected Model | CBPostTS | 751.183 | 2 | 375.591 | 40.290 | .000 | .449 |
GOPostTS | 198.248 | 2 | 99.124 | 3.427 | .036 | .065 | |
SCPostTS | 611.734 | 2 | 305.867 | 32.089 | .000 | .393 | |
SEPostTS | 206.212 | 2 | 103.106 | 24.015 | .000 | .327 | |
TVPostTS | 243.506 | 2 | 121.753 | 5.345 | .006 | .097 | |
Intercept | CBPostTS | 25029.569 | 1 | 25029.569 | 2684.921 | .000 | .964 |
GOPostTS | 81489.363 | 1 | 81489.363 | 2817.003 | .000 | .966 | |
SCPostTS | 44934.147 | 1 | 44934.147 | 4714.179 | .000 | .979 | |
SEPostTS | 21093.959 | 1 | 21093.959 | 4913.156 | .000 | .980 | |
TVPostTS | 151771.322 | 1 | 151771.322 | 6662.655 | .000 | .985 | |
Groups | CBPostTS | 751.183 | 2 | 375.591 | 40.290 | .000 | .449 |
GOPostTS | 198.248 | 2 | 99.124 | 3.427 | .036 | .065 | |
SCPostTS | 611.734 | 2 | 305.867 | 32.089 | .000 | .393 | |
SEPostTS | 206.212 | 2 | 103.106 | 24.015 | .000 | .327 | |
TVPostTS | 243.506 | 2 | 121.753 | 5.345 | .006 | .097 | |
Error | CBPostTS | 922.905 | 99 | 9.322 | |||
GOPostTS | 2863.840 | 99 | 28.928 | ||||
SCPostTS | 943.639 | 99 | 9.532 | ||||
SEPostTS | 425.043 | 99 | 4.293 | ||||
TVPostTS | 2255.161 | 99 | 22.779 | ||||
Total | CBPostTS | 26553.000 | 102 | ||||
GOPostTS | 85229.000 | 102 | |||||
SCPostTS | 46874.000 | 102 | |||||
SEPostTS | 21932.000 | 102 | |||||
TVPostTS | 155000.000 | 102 |
Dependent Variable | (I) Study Groups | (J) Study Groups | Mean Difference (I-J) | Std. Error | Sig. | 95% Confidence Interval | |
---|---|---|---|---|---|---|---|
Lower Bound | Upper Bound | ||||||
CBPostTS | EG1 | EG2 | 5.21 | .735 | .000 | 3.46 | 6.96 |
CG | 6.49 | .769 | .000 | 4.66 | 8.32 | ||
EG2 | EG1 | -5.21 | .735 | .000 | -6.96 | -3.46 | |
CG | 1.28 | .728 | .189 | -.45 | 3.01 | ||
GOPostTS | EG1 | EG2 | 2.00 | 1.294 | .274 | -1.08 | 5.08 |
CG | 3.54 | 1.355 | .028 | .31 | 6.76 | ||
EG2 | EG1 | -2.00 | 1.294 | .274 | -5.08 | 1.08 | |
CG | 1.54 | 1.283 | .457 | -1.51 | 4.59 | ||
SCPostTS | EG1 | EG2 | 2.87 | .743 | .001 | 1.10 | 4.64 |
CG | 6.22 | .778 | .000 | 4.37 | 8.07 | ||
EG2 | EG1 | -2.87 | .743 | .001 | -4.64 | -1.10 | |
CG | 3.35 | .736 | .000 | 1.60 | 5.10 | ||
SEPostTS | EG1 | EG2 | 1.52 | .499 | .008 | .33 | 2.71 |
CG | 3.60 | .522 | .000 | 2.36 | 4.84 | ||
EG2 | EG1 | -1.52 | .499 | .008 | -2.71 | -.33 | |
CG | 2.08 | .494 | .000 | .90 | 3.25 | ||
TVPostTS | EG1 | EG2 | 3.46 | 1.148 | .009 | .73 | 6.19 |
CG | 3.22 | 1.203 | .023 | .36 | 6.08 | ||
EG2 | EG1 | -3.46 | 1.148 | .009 | -6.19 | -.73 | |
CG | -.24 | 1.138 | .975 | -2.95 | 2.47 |
CB | Control Belief |
GIBI | Guided Inquiry-Based Instruction |
GO | Goal Orientation |
SB | Self-Belief |
SC | Self-Concept |
SE | Self-Efficacy |
TV | Task Value |
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APA Style
Yeshanew, A., Belachew, T., Gezahegn, H., Tesfa, T. (2024). Effects of Variation Theory Integrated Guided Inquiry-Based Instruction on Grade Ten Students Self-Belief in Learning Solid Geometry. International Journal of Secondary Education, 12(3), 56-67. https://doi.org/10.11648/j.ijsedu.20241203.12
ACS Style
Yeshanew, A.; Belachew, T.; Gezahegn, H.; Tesfa, T. Effects of Variation Theory Integrated Guided Inquiry-Based Instruction on Grade Ten Students Self-Belief in Learning Solid Geometry. Int. J. Second. Educ. 2024, 12(3), 56-67. doi: 10.11648/j.ijsedu.20241203.12
AMA Style
Yeshanew A, Belachew T, Gezahegn H, Tesfa T. Effects of Variation Theory Integrated Guided Inquiry-Based Instruction on Grade Ten Students Self-Belief in Learning Solid Geometry. Int J Second Educ. 2024;12(3):56-67. doi: 10.11648/j.ijsedu.20241203.12
@article{10.11648/j.ijsedu.20241203.12, author = {Abebaw Yeshanew and Tesfu Belachew and Habtamu Gezahegn and Tadele Tesfa}, title = {Effects of Variation Theory Integrated Guided Inquiry-Based Instruction on Grade Ten Students Self-Belief in Learning Solid Geometry }, journal = {International Journal of Secondary Education}, volume = {12}, number = {3}, pages = {56-67}, doi = {10.11648/j.ijsedu.20241203.12}, url = {https://doi.org/10.11648/j.ijsedu.20241203.12}, eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ijsedu.20241203.12}, abstract = {In mathematics education, students’ beliefs that could take many different forms like students' beliefs about mathematics learning mathematics teaching; and about themselves play a significant role in their learning and achievement. In particular, self-belief (SB) that is students’ evaluation and judgment about themselves in learning solid geometry, which encompassing control belief (CB), goal orientation (GO), self-concept (SC), self-efficacy (SE), and task value (TV), is critical to their success in learning solid geometry. Addressing these SB dimensions can substantially improve students' learning outcomes in solid geometry. Innovative, student-centered instructional approaches like GIBI, especially when combined with variation theory, offer a potential solution for overcoming Ethiopian secondary schools’ educational challenges by promoting active learning and providing varied examples to enhance engagement and achievement. However, there is a lack of research on the effectiveness of this combined approach in Ethiopia context. This study aims to fill this gap by investigating the effects of variation theory integrated GIBI on grade ten students' SB in learning solid geometry in Ethiopia. Employing a quasi-experimental with non-equivalent control group pretest-posttest design, 102 students from three public secondary schools in Debre Tabor city, Amhara region were randomly assigned into three groups: Experimental Group 1 (EG1) received GIBI with variation theory, Experimental Group 2 (EG2) received GIBI without variation theory, and the Control Group (CG) received traditional teaching methods. A SB questionnaire was used to measure students' CB, GO, SC, SE, and TV before and after the intervention. The results revealed significant improvements in the SB dimensions among students in EG1 compared to those in EG2 and CG. Specifically, EG1 students showed higher post-test scores in CB (F (2,99)=40.29, p=0.000, η²=0.449); GO (F (2,99)=3.43, p=0.036, η²=0.065); SC (F (2,99)=32.09, p=0.000, η²=0.393); SE (F (2,99)=24.02, p=0.000, η²=0.327); and TV (F (2,99)=5.35, p=0.000, η²=0.097). Tukey post hoc tests indicated that EG1 students' scores were significantly higher than those of the CG in CB and GO, and higher than EG2 and CG in SC, SE, and TV. These findings suggest that the integration of variation theory with GIBI effectively enhances students' SB in learning solid geometry, thereby addressing the educational challenges faced by Ethiopian students. The study recommends adopting this instructional approach more widely to improve student outcomes in mathematics. }, year = {2024} }
TY - JOUR T1 - Effects of Variation Theory Integrated Guided Inquiry-Based Instruction on Grade Ten Students Self-Belief in Learning Solid Geometry AU - Abebaw Yeshanew AU - Tesfu Belachew AU - Habtamu Gezahegn AU - Tadele Tesfa Y1 - 2024/09/20 PY - 2024 N1 - https://doi.org/10.11648/j.ijsedu.20241203.12 DO - 10.11648/j.ijsedu.20241203.12 T2 - International Journal of Secondary Education JF - International Journal of Secondary Education JO - International Journal of Secondary Education SP - 56 EP - 67 PB - Science Publishing Group SN - 2376-7472 UR - https://doi.org/10.11648/j.ijsedu.20241203.12 AB - In mathematics education, students’ beliefs that could take many different forms like students' beliefs about mathematics learning mathematics teaching; and about themselves play a significant role in their learning and achievement. In particular, self-belief (SB) that is students’ evaluation and judgment about themselves in learning solid geometry, which encompassing control belief (CB), goal orientation (GO), self-concept (SC), self-efficacy (SE), and task value (TV), is critical to their success in learning solid geometry. Addressing these SB dimensions can substantially improve students' learning outcomes in solid geometry. Innovative, student-centered instructional approaches like GIBI, especially when combined with variation theory, offer a potential solution for overcoming Ethiopian secondary schools’ educational challenges by promoting active learning and providing varied examples to enhance engagement and achievement. However, there is a lack of research on the effectiveness of this combined approach in Ethiopia context. This study aims to fill this gap by investigating the effects of variation theory integrated GIBI on grade ten students' SB in learning solid geometry in Ethiopia. Employing a quasi-experimental with non-equivalent control group pretest-posttest design, 102 students from three public secondary schools in Debre Tabor city, Amhara region were randomly assigned into three groups: Experimental Group 1 (EG1) received GIBI with variation theory, Experimental Group 2 (EG2) received GIBI without variation theory, and the Control Group (CG) received traditional teaching methods. A SB questionnaire was used to measure students' CB, GO, SC, SE, and TV before and after the intervention. The results revealed significant improvements in the SB dimensions among students in EG1 compared to those in EG2 and CG. Specifically, EG1 students showed higher post-test scores in CB (F (2,99)=40.29, p=0.000, η²=0.449); GO (F (2,99)=3.43, p=0.036, η²=0.065); SC (F (2,99)=32.09, p=0.000, η²=0.393); SE (F (2,99)=24.02, p=0.000, η²=0.327); and TV (F (2,99)=5.35, p=0.000, η²=0.097). Tukey post hoc tests indicated that EG1 students' scores were significantly higher than those of the CG in CB and GO, and higher than EG2 and CG in SC, SE, and TV. These findings suggest that the integration of variation theory with GIBI effectively enhances students' SB in learning solid geometry, thereby addressing the educational challenges faced by Ethiopian students. The study recommends adopting this instructional approach more widely to improve student outcomes in mathematics. VL - 12 IS - 3 ER -