Thinking, N. R. C. (US) C. for the W. on C., & Council, N. R. (2010). Report of a workshop on the scope and nature of computational thinking. Natl Academy Pr.
Tolboom, J. (1999). The first year of the CODI curriculum. Informatie bulletin I&I, 9–11.
Tolboom, J., Kruger, J., & Grgurina, N. (2014). Informatica in de bovenbouw havo/vwo: Naar aantrekkelijk en actueel onderwijs in informatica. SLO.
Touretzky, D. S., Marghitu, D., Ludi, S., Bernstein, D., & Ni, L. (2013). Accelerating K-12 computational thinking using scaffolding, staging, and abstraction. Proceeding of the 44th ACM technical symposium on Computer science education, 609–614.
Tweede Fase Adviespunt. (2006). Veranderingen Tweede Fase en docenten: Volgen of meebeslissen (Vol. 2008).
Vaandrager, F. (2011). A First Introduction to uppaal. Deliverable no.: D5.12 Title of Deliverable: Industrial Handbook, 18.
Vahrenhold, J., Nardelli, E., Pereira, C., Berry, G., Caspersen, M. E., Gal-Ezer, J., Kölling, M., McGettrick, A., & Westermeier, M. (2017). Informatics Education in Europe: Are We All In The Same Boat.
Van der Laan, Krikke, H., Kievit, D., & Bosschaart, E. (2001). Fundament Informatica (2 ed.). Instruct.
Vogel, S., Santo, R., & Ching, D. (2017). Visions of computer science education: Unpacking arguments for and projected impacts of CS4All initiatives. Proceedings of the 2017 ACM SIGCSE Technical Symposium on Computer Science Education, 609–614.
Walden, J., Doyle, M., Garns, R., & Hart, Z. (2013). An informatics perspective on computational thinking. Proceedings of the 18th ACM conference on Innovation and technology in computer science education, 4–9. https://doi.org/10.1145/2462476.2483797
Weert, T. V., & Tinsley, D. (1994). Informatics for secondary education: A curriculum for schools. UNESCO.
Weintrop, D., & Wilensky, U. (2013). Robobuilder: A computational thinking game. SIGCSE, 736.
Weintrop, D., Beheshti, E., Horn, M., Orton, K., Jona, K., Trouille, L., & Wilensky, U. (2016). Defining computational thinking for mathematics and science classrooms. Journal of Science Education and Technology, 25(1), 127–147.
Weller, M. P., Do, E. Y. L., & Gross, M. D. (2008). Escape machine: Teaching computational thinking with a tangible state machine game. Proceedings of the 7th international conference on Interaction design and children, 282–289.
Werner, L., Denner, J., Campe, S., & Kawamoto, D. C. (2012). The Fairy Performance Assessment: Measuring Computational Thinking in Middle School. Proceedings of the 43rd ACM technical symposium on Computer Science Education, 215–220. https://doi.org/10.1145/2157136.2157200
Whalley, J., Clear, T., Robbins, P., & Thompson, E. (2011). Salient elements in novice solutions to code writing problems. Proceedings of the Thirteenth Australasian Computing Education Conference- Volume 114, 37–46.
Wilensky, U. (1997). NetLogo Wolf Sheep Predation model. http://www.netlogoweb.org
Wilensky, U. (1999). NetLogo. http://www.netlogoweb.org
Wilensky, U. (2014). Computational thinking through modeling and simulation. Whitepaper presented at the summit on future directions in computer education. Orlando, FL. http://www.stanford.edu/ coopers/2013Summit/WilenskyUriNorthwesternREV.pdf.
Wilensky, U., & Papert, S. (2010). Restructurations: Reformulations of knowledge disciplines through new representational forms. Constructionism.
Wilensky, U., & Rand, W. (2015). An introduction to agent-based modeling: Modeling natural, social, and engineered complex systems with NetLogo. MIT Press.
Wilensky, U., Brady, C. E., & Horn, M. S. (2014). Fostering computational literacy in science classrooms. Communications of the ACM, 57(8), 24–28.
Wilson, C. (2010). Running the Empty: Failure to Teach K-12 Computer Science in the Digital Age.
Association for Computing Machinery. R
Wing, J. M. (2006). Computational thinking. Communications of the ACM, 49(3), 33–35.
Wing, J. M. (2008). Computational Thinking and Thinking about Computing. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 366(1881), 3717.
References
195