International Journal of Technology and Design Education 7: 161-180, 1997. 1997
Instructional Principles and Strategies for Enhancing Cognitive Learning
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Instructional Principles and Strategies
for Enhancing Cognitive Learning 176 SCOTT D. JOHNSON
177 “micro-apprenticeships,” one-to-one tutoring, and authentic project-centred problems. Is instructional practice in technology education determined through an understanding of contemporary learning theory and research or is it based primarily on common sense and tradition? Even though many of the desired instructional characteristics discussed in this chapter are evident in technology education, the reasons for their existence are not clear. The field has been criticized for placing too much emphasis on developing basic technical skills and competencies rather than the higher level cognitive skills. It seems as though the field is using cognitive-oriented instructional practices to achieve motor skill development and the learning of work procedures, goals that can be addressed through behavioural learning theories. This has resulted in instruction that is delivered through lectures and demonstrations, emphasizes memorizing information, teaches large skill sets as small discrete tasks, and encourages practice of technical skills until they can be performed accurately. Because the courses are taught in laboratories or “shops” and students are actively using tools and equipment to complete projects, one might hope that the development of intellectual skills would be an integral focus in the courses. While those skills are enhanced through technical instruction, it occurs because of the richness of the learning environment and not because those skills are explicitly emphasized in the course. In essence, the intellectual skills that are developed through technology education are a byproduct of the learning environment and not a result of an explicit and conscious effort by the curriculum designers and instructors. If intellectual skill development is to become a larger focus of the technology curriculum, a better understanding of social-constructionist theories of learning are needed. This does not imply that the behavioural theories of learning be tossed aside in favour of the more contemporary social- constructionist theories. Instructional designers and technology instructors need to match their desired learning goals and instructional methods to the appropriate learning theories. Royer (1986) provides a taxonomy of educational goals that helps clarify which learning theories are appropriate for the different types of learning that occur in technology education. Those learning goals include memorization of important information, development of motor skills, understanding concepts and relationships, and enhancement of intellectual skills such as problem solving and decision making. Designing instruction around the behavioral learning theories is appropriate when the learning goal is to help students remember important information or to develop their skill in using and operating tools and equipment. These types of goals are prevalent in technology education and the behavioral approaches have served the field well. However, because of the changing nature of the workplace and society, there is an increased need to emphasize learning goals that involve the development of understanding and the improvement of intellectual skills. These types of goals require that instruction be designed
SCOTT D. JOHNSON around the social-constructivist learning theories. This will result in the design of stimulating learning environments in which flexible, highly active, group and project-oriented methods are used. The four elements of informal learning and the instructional principles and strategies shown in Figure 2 provide a starting point for selecting appropriate instructional methods that enhance understanding and the development of intellectual skills. REFERENCES Andre, T.: 1986, ‘Problem Solving and Education’, in G. D. Phye & T. Andre (eds.), Cognitive Classroom Learning: Understanding, Thinking, and Problem Solving, Academic Press, New York, 169-204. Balfanz, R.: 1991, ‘Local Knowledge, Academic Skills, and Individual Productivity: An Alternative View’, Educational Policy 5(4), 343-370. Bereiter, C.: 1984, ‘How to Keep Thinking Skills from Going the Way of All Frills’, Educational Leadership 42(1), 75-77. Berryman, S. & Bailey, T.: 1992, The Double Helix of Education and the Economy, Columbia University, Teacher College, The Institute on Education and the Economy, New York. Biemiller, A.: 1993, ‘Lake Wobegon Revisited: On Diversity and Education’, Educational Researcher 22(9), 7-12. Bransford, J. D. (ed.).: 1979, Human Cognition: Learning, Understanding and Remembering, Wadsworth, Belmont, CA. Bransford, J. D., Sherwood, R. S., Hasselbring, T. S., Kinzer, C. K. & Williams, S. M.: 1990, ‘Anchored Instruction: Why We Need It and How Technology Can Help’, in D. Nix & R. Spiro (eds.), Advances in Computer-video Technology, Erlbaum, Hillsdale, NJ. Brookfield, S. D.: 1984, ‘Self-directed Adult Learning: A Critical Paradigm’, Adult Education Quarterly 35, 59-71. Brown, A. L.: 1978, ‘Knowing When, Where, and How to Remember: A Problem of Metacognition’, in R. Glaser (ed.), Advances in Instructional Psychology (Vol. 1), Erlbaum, Hillsdale, NJ, 77-165. Brown, A. L.: 1994, ‘The Advancement of Learning’, Educational Researcher 23(8), 4-12. Brown, A. L. & Campione, J. C.: 1990, ‘Communities of Learning and Thinking, or a Context by Any Other Name’, in D. Kuhn (ed.). Contributions to Human Development 21, 108-125. Brown, J. S., Collins, A. & Duguid, P.: 1989, ‘Situated Cognition and the Culture of Learning’, Educational Researcher 18(1), 32-42. Caffarella, R. S. & O’Donnell, J. M.: 1987, ‘Self-directed Adult Learning: A Critical Paradigm Revisited’, Adult Education Quarterly 37, 199-211. Chase, W. G. & Simon, H. A.: 1973, ‘The Mind’s Eye in Chess’, in W. G. Chase (ed.), Visual Information Processing, Academic, New York, 215-281. Chi, M. T. H., Feltovich, P. J. & Glaser, R.: 1981, ‘Categorization and Representation of Physics Problems by Experts and Novices’, Cognitive Science 5, 121-152. Clark, R. E. & Voogel, A.: 1985, ‘Transfer of Training Principles for Instructional Design’, Educational Communication and Technology Journal 33(2), 113-123. Collins, A., Brown, J. S. & Newman, S. E.: 1989, ‘Cognitive Apprenticeship: Teaching the Craft of Reading, Writing, and Mathematics’, in L. B. Resnick (ed.), Knowing, Learning, and Instruction: Essays in Honor of Robert Glaser, Erlbaum, Hillsdale, NJ, 453-494. Diehl, W. A. & Mikulecky, L.: 1980, ‘The Nature of Reading at Work’, Journal of Reading 24(3), 221-227. Ellis, A. K. & Fouts, J. T.: 1993, Research on Educational Innovations, Eye on Education, Princeton, NJ. Yüklə 47,04 Kb. Dostları ilə paylaş:
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