Showing total 4 results

1. Automation and Schema Acquisition in Learning Elementary Computer Programming: Implications for the Design of Practice.

Author

Van Merrienboer, Jeroen J. G. and Paas, Fred G. W. C.

Abstract

Discussion of computer programing at the secondary level focuses on automation and schema acquisition as two processes important in learning cognitive skills such as programing. Their effects on learning outcomes and transfer of training are examined, the importance of worked examples is highlighted, and instructional design principles are presented. (60 references) (LRW)

Published

1990

2. Liveware: The Next Challenge in Computer Education.

Author

Thompson, Ann D.

Abstract

Discusses the complexity of educating teachers so that they can effectively utilize educational software and integrate it into the curriculum. The cognitive orientation of computer learning environments is emphasized, preservice and inservice experiences are suggested, learning theories are discussed, and a sample experience for teachers using Logo is described. (17 references) (Author/LRW)

Published

1989

3. Informatics meets foreign languages COOL ideas for a cross-curricular cooperation

Author

Sabitzer, Barbara

Subjects

*COMPUTER science education, *SECONDARY education, *MIDDLE school student attitudes, *INTERDISCIPLINARY education, *EDUCATION, *FOREIGN language education, *INFORMATION & communication technologies, *COMPUTER assisted instruction, *COGNITIVE psychology, *COMPUTER science, *CURRICULUM, *INFORMATION science, *LEARNING strategies, *RESEARCH, *SCHOOL environment, *TEACHING methods

Abstract

Informatics or computer science (the terms informatics and computer science are used as synonyms in this paper) in Austrian secondary schools is often considered “difficult” and “not interesting” because of mainly mathematical and economical contents. But informatics is much more; it is used in almost every part of the working life and can also cooperate with every subject at school. It offers a wide range of possibilities for COOL (COoperative Open Learning), an Austrian teaching model based on the Dalton Plan that provides also cooperation between different subject matters. Besides the COOL concept this paper describes some ideas for cooperation between informatics and foreign languages at secondary schools and at University level besides just ICT (Information and Communication Technology) or computer-assisted language learning. The presented tasks are part of the project “COOL Informatics” (according to COoperative Open Learning) that aims at developing COOL teaching material based on neurodidactical (Neurodidactics is a relatively young research field that combines the findings of brain research, pedagogy, cognitive psychology and other related fields.) principles for informatics and cross-curricular cooperation from primary school up to University. On the basis of the developed material the following main research questions of the project shall be examined in the course of the next school year: (1) Can COoperative Open Learning methods help to enhance learning? (2) Can learning be enhanced by considering neurodidactical principles in the design of teaching material and in the classroom? As the first test phase of the developed material is still in progress the evaluation is not available at the moment. But the first informal feedback of a vocational school and a programming course at the University shows that it is worth fostering COoperative Open Learning and cross-curricular cooperation. [Copyright &y& Elsevier]

Published

2013

4. Review on teaching and learning of computational thinking through programming: What is next for K-12?

Author

Lye, Sze Yee and Koh, Joyce Hwee Ling

Subjects

*COMPUTER assisted instruction, *EXPERIMENTAL design, *HIGH school students, *LEARNING strategies, *MIDDLE school students, *PROBLEM solving, *PROGRAMMING languages, *SCHOOL children, *THOUGHT & thinking, *TEACHING methods

Abstract

Programming is more than just coding, for, it exposes students to computational thinking which involves problem-solving using computer science concepts like abstraction and decomposition. Even for non-computing majors, computational thinking is applicable and useful in their daily lives. The three dimensions of computational thinking are computational concepts, computational practices and computational perspectives. In recent years, the availability of free and user-friendly programming languages has fuelled the interest of researchers and educators to explore how computational thinking can be introduced in K-12 contexts. Through an analysis of 27 available intervention studies, this paper presents the current trends of empirical research in the development of computational thinking through programming and suggests possible research and instructional implications. From the review, we propose that more K-12 intervention studies centering on computational practices and computational perspectives could be conducted in the regular classroom. To better examine these two dimensions, students could be asked to verbalize their thought process using think aloud protocol while programming and their on-screen programming activity could be captured and analyzed. Predetermined categories based on both past and recent programming studies could be used to guide the analysis of the qualitative data. As for the instructional implication, it is proposed that a constructionism-based problem-solving learning environment, with information processing, scaffolding and reflection activities, could be designed to foster computational practices and computational perspectives. [ABSTRACT FROM AUTHOR]

Published

2014