Journal of Woman in Culture and Arts

Current Issue

By Issue

By Author

By Subject

Author Index

Keyword Index

About Journal

Aims and Scope

Editorial Board

Publication Ethics

Indexing and Abstracting

Related Links

FAQ

Peer Review Process

Terms and conditions of submitting an article

Paper Preparation Guide

Forms

Publons Membership and Review Guide

Reviewers

Explanation women's Artistic Sketches based on Scientific Epistemological Beliefs with the role of Cognitive Load mediator in Architectural Design Education

Document Type : Research Paper

Author

Department of Architecture, College of Art and Architecture, Hamedan Branch, Islamic Azad University, Hamedan, Iran

Abstract

The design process in architecture is one of the curricula of the field of architecture that is taught at different educational levels. For optimal educational planning, it is necessary to identify the variables related to it. Among the variables related to the design process and method are the epistemological beliefs and cognitive load of the learners. The purpose of the current research was to investigate the relationship between scientific epistemological and cognitive load with ideation in the design process of architecture students. The research method is a combination of quantitative (descriptive-correlation) and qualitative (analyzing samples of students' Sketches). Its statistical population included all architecture girl students in Hamadan universities. The desired sample of 120 people was selected in an accessible way. Scientific epistemology, cognitive load and idea evaluation scale questionnaires were used in the design. The research data were analyzed by descriptive statistics (mean, standard deviation, skewness and skewness statistics) and inferential statistics (Pearson's correlation and path analysis with the calculation of its defaults). The results of the research showed that there is a relationship between the beliefs of scientific epistemology and cognitive load with ideation in the design process of architecture students and it has provided a framework for recognizing and explaining the theoretical relationships between the components of scientific epistemological beliefs, cognitive load and the idea of sketches. The learning process in architectural design and cartography courses includes the stages of analytical comprehension, critical thinking, and creative processing, so scientific epistemological belief and cognitive balance or cognitive load are good explanations and predictors for ideas in students. Based on the results of the research, it is suggested to pay attention to the reduction of Intrinsic and Extraneous cognitive load in planning the education of architecture students, as well as Germane cognitive processing so that they can make better progress in the field of design. The development of scientific epistemological beliefs is also recommended for generating and analyzing ideas.

Keywords

Main Subjects

References
Alipour, L. (2019). Improving precedent-based architectural design ideation with action research methodology. Journal of Fine Arts: Architecture & Urban Planning, 24(3), 47-60. (In Persian)
Amini, S., Falamaki, M. M., & Keramati, G. (2019). Typology of imagination in the process of architectural design. The Monthly Scientific J. of Bagh-e Nazar, 16(72), 53-64. (In Persian)
Amir Timuri, M. H., & Zare, M. (2014). Cognitive load and multimedia education. Tehran: Allameh Tabatabai University. (In Persian)
Biyabangard, I. (2011). Educational psychology. Tehran: Virayesh. (In Persian)
Bolkhari, H. (2010). Women and Art. Women's Strategic Studies, 12(47), 171-196. (In Persian)
Brunken, R., Plass, J. L., & Leutner, D. (2003). Direct measurement of cognitive load in multimedia learning. Educational Psychologist38(1), 53-61.
Conley, M. A., Pintrich, R. P., Vekiri, L., & Harrison, D. (2004). Changes in epistemological beliefs in elementary science students. Contemporary Educational Psychology, 29, 186-204.
De Jong, T. (2010). Cognitive load theory, educational research and instructional designs: some food for more thought. Instructional Science, 38, 105-134.
De Koning, N. (2021). Could Combining Growth Mindset and Task Complexity Affect Motivation, Cognitive Load, and Performance? An Experimental Study. Master Educational Sciences. Open University.
Deng, A., & Chen, A. (2023). Contributions of tasks with different cognitive load to high school students’ in-class physical activity. Journal of Teaching in Physical Education42(4), 684-695.
Dimov, B. C., Atanasoska, T., Iliev, D., Trajkovska, D. A., & Kuzmanovska, M. S. (2015). Importance of investment in research's of students and teachers epistemological and pedagogical beliefs. Procedia-Social and Behavioral Sciences, 191, 1299-1303.
Hofer, B., & Pinterich, P. R. (2002). The developmental epistemological theories: belief about knowledge and knowing and their relation to learning. Review of Educational Research, 88-140.
Jiang, D., & Kalyuga, S. (2020). Confirmatory factor analysis of cognitive load ratings supports a two-factor model. Tutorial in Quantitative Methods for Psychology, 16(3), 216-225.
Kadkhodaee, M., & Soleimani, A. (2015). Comparing the effect of synectics and lecturing teaching methods on increasing the creativity of the third grade of elementary school students (considering Zarinshahr Schoolgirls and Schoolboys). Research in Curriculum Planning, 45, 119-130. (In Persian)
Kalyuga S. (2012). Managing cognitive load in adaptive multimedia learning. New York: Hershey.
Lang, J. (2014). Creation of architectural theory: The role of behavioral sciences in environmental design. Translated by: A. Ainifar. Tehran: Tehran University Press. (In Persian)
Lawson, B. (2012). How designers think: Demystifying the design process. Translated by: H. Nadimi. Tehran: Shahid Beheshti University. (In Persian)
 Liu, Q., Yu, S., Chen, W., Wang, Q., & Xu, S. (2021). The effects of an augmented reality based magnetic experimental tool on students' knowledge improvement and cognitive load. Journal of Computer Assisted Learning37(3), 645-656.
Mesrabadi, J., & Ashrafzade, T. (2021). A Meta-Analysis of the Relationship Epistemological Beliefs and Academic Performance. Biquarterly Journal of Cognitive Strategies in Learning, 9(17), 71-90. (In Persian)
Moameni Mahmouei, H., & Aujineghad, A. R. (2010). The Impact of Syntactic Teaching Model on Improving Students Creativity in Composition Lessons. Educational Psychology, 1(2), 90-102. (In Persian)
Nadimi, H., & Shariat Rad, F. (2012). Sources of architectural design ideation a reflection on the ideation process of eight iranian professional architects. Journal of Fine Arts: Architecture & Urban Planning, 17(2), 5-14. (In Persian)
Niusha, B., Pakdaman, A., & Ovaysi, Z. (2013). Investigating the roll of synectics teaching pattern on art creativity and its differences between girls and boys. Innovation and Creativity in Human Science, 2(4), 159-176. (In Persian)
Orgun, F., Karaoz, B. (2013). Epistemological beliefs and the self-efficacy scale in nursing students. Nurse Education Today, 34(6), 37-40.
 Özbay, H. E., & Köksal, M. S. (2021). Middle school students’ scientific epistemological beliefs, achievements in science and intellectual risk-taking. Science & Education30(5), 1233-1252.
Paas, F., Van Gog, T., & Sweller, J. (2010). Cognitive load theory: New conceptualizations, specifications, and integrated research perspectives. Educational Psychology Review, 22(2), 115-121.
 
Pappas, C. (2014). Cognitive Load Theory and Instructional Design - eLearning Industry. Educational Technology for Learning.
Pass, F., Renkl, A., & Sweller, J. (2010). Cognitive load theory and instructional design: Recent developments. Educational Psychology, 38, 1-4.
Perchtold, S., Corinna, M., Rominger, C., Papousek, I., & Fink, A. (2023). Women and men have a similar potential for malevolent creativity – But their underlying brain mechanisms are different. Brain Research, 1801.
Rahnama, A., Norouzi, M., & Jahani Javanmardi, F. (2018). Investigate the relationship between epistemological beliefs with elements of teaching faculty (Shahed University Study). Biquarterly Journal of Cognitive Strategies in Learning, 6(10), 151-169. (In Persian)
Rashidi, E., & Shahrari, M. (2008). A study of the relationship between creativity with locus of control. innovation in management education. Journal of Modern Thoughts in Education, 3(3), 81-99. (In Persian)
Rasouli, M., Shadmehri, N., & Angouti, Z. (2023). A study of the Effectiveness of a LEGO computer game on the creative thinking of preschool girls and boys. Thinking and Children, 14(1), 131-148. (In Persian)
Saif, A.A. (2011). Educational measurement, assessment and evaluation (6th Ed.). Tehran: Duran Publishing House. (In Persian)
Salama, A. (2005). Skill-based/knowledge-based architectural pedagogies: An argument for creating humane environments. The 7th International conference Humane Habital-ICHH.
 Salden, R. J., Paas, F., & van Merriënboer, J. J. (2006). A comparison of approaches to learning task selection in the training of complex cognitive skills. Computers in Human Behavior22(3), 321-333.
Schnotz, W., Fries, S., & Horz, H. (2009). Motivational aspects of cognitive load theory. In M. Wosnitza, S. A. Karabenick, A. Efklides., & P. Nenniger (Eds.), Contemporary motivation research: From global to local perspectives (pp. 69–96). New York.
Schommer, M. (1992). The effects of beliefs about the nature of knowledge on comprehension. A Doctoral Thesis, University of Illinois, Urbana.
Seif, D., & Marzooghi, R.A. (2009). The relationship between the dimensions of epistemological beliefs, self-efficacy and academic achievement in physical sciences among guidance school students. Daneshvar Raftar, 15(33), 1-14. (In Persian)
 
Sharif, H. R., & Nadimi, H. (2013). Ideation versus idea processing in architectural design thinking. Soffeh, 23(3), 19-26. (In Persian)
Skulmowski, A., & Xu, K. M. (2021). Understanding cognitive load in digital and online learning: a new perspective on extraneous cognitive load. Educational Psychology Review.
Smith, C. L., & Wenk, L. (2006). Epistemologies of science Relations among three aspects of first‐year college students. Journal of Research in Science Teaching, 43(8), 747-785.
Smith, P. L., & Ragan, T. J. (2005). Instructional design (3rd Ed.). Hoboken, NJ: Sons, Inc.
Sweller J. (2004). Instructional design consequences of an analogy between evolution by natural selection and human cognitive architecture. Instructional Science, 32(1), 9-31.
Sweller, J., Van Merriënboer, J. J. G., & Paas, F. (2019). Cognitive architecture and instructional design: 20 years later. Educational Psychology Review, 31(2), 61–292.
Szulewski, A., Howes, D., van Merriënboer, J. J., & Sweller, J. (2021). From theory to practice: the application of cognitive load theory to the practice of medicine. Academic Medicine96(1), 24-30.
Tenenhaus, M., & Amato, S. (2004). A global Goodness–of–Fit index for PLS structural equation modelling. ESIS (European Satisfaction Index System.
Thees, M., Kapp, S., Strzys, M. P., Beil, F., Lukowicz, P., & Kuhn, J. (2020). Effects of augmented reality on learning and cognitive load in university physics laboratory courses. Computers in Human Behavior108, 106316.
Wetzels, M., Odekerken-Schröder, G., & Van Oppen, C. (2009). Using PLS path modeling for assessing hierarchical construct models: Guidelines and empirical illustration. MIS Quarterly, 33(1), 177-195.
Wu, Y‐T., & Tsai, C‐C. (2011). High school students’ informal reasoning regarding a socio‐scientific issue, with relation to scientific epistemological beliefs and cognitive structures. International Journal of Science Education, 33, 371-400.
Zareh, M., & Houmayoni, A. (2019). Modeling Structural Relationships Between Epistemological Beliefs and Mediating Learning Strategies on Anxiety in English Students. Education Strategies in Medical Sciences, 12(2), 1-10. (In Persian)
Journal of Woman in Culture and Arts
Volume 16, Issue 1
June 2024
Pages 61-84
Files
Share
How to cite
Statistics