Abstract
In recent years, there has been an increasing national focus on the importance of Science, Technology, Engineering, and Math (STEM) education for young children beginning in kindergarten. This chapter explores the newest acronym, “STEAM,” which integrates the Arts with STEM education. While many assume the “A” in STEAM refers only to the fine arts, the full potential of STEAM goes beyond aesthetics to include language arts, culture, history, and the humanities . The emerging domain of robotics offers playful strategies for engaging young children with the technology and engineering components of STEM. Additionally, when implemented thoughtfully, robotics is a creative medium with the power to engage young children in the arts and humanities. KIBO is a newly developed robotics construction set specifically designed for children ages 4–7 years to learn foundational engineering and programming content in a hands-on, open-ended way—no screen-time required! This chapter presents vignettes of three interdisciplinary robotics curricular units that utilize the KIBO Robotics Kit: (1) Dances from Around the World, (2) Art-Making Robots, and (3) Superhero Bots. It highlights strategies for taking a child-focused approach to robotics education by drawing on student interest in music, visual arts, and literature when exploring foundational technological ideas.
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Andress, B. (1980). Music experiences in early childhood. New York, NY: Schirmer Books.
Ackermann, E. (2001). Piaget’s constructivism, Papert’s constructionism: What’s the difference. Future of Learning Group Publication, 5(3), 438.
Althouse, R., Johnson, M. H., & Mitchell, S. T. (2003). The colors of learning: Integrating the visual arts into the early childhood curriculum. New York: Teachers College Press.
American Academy of Pediatrics. (2003). Prevention of pediatric overweight and obesity: Policy statement. Pediatrics, 112, 424–430.
Bers, M. U. (2008). Blocks to robots: Learning with technology in the early childhood classroom. NY: Teachers College Press.
Bers, M. U. (2010). The TangibleK Robotics Program: Applied computational thinking for young children. Early Childhood Research and Practice, 12(2).
Bers, M. U. (2012). Designing digital experiences for positive youth development: From playpen to playground. Oxford: Oxford University Press.
Bers, M. U. (2017). Coding as a playground: Programming and computational thinking in the early childhood classroom. Routledge press.
Bers, M. U., Ponte, I., Juelich, K., Viera, A., & Schenker, J. (2002). Teachers as designers: Integrating robotics into early childhood education. Information Technology in Childhood Education, 123–145.
Bers, M. U., Seddighin, S., & Sullivan, A. (2013). Ready for robotics: Bringing together the T and E of STEM in early childhood teacher education. Journal of Technology and Teacher Education, 21(3), 355–377.
Brosterman, N. (1997). Inventing kindergarten. New York: H.N. Abrams.
Cejka, E., Rogers, C., & Portsmore, M. (2006). Kindergarten robotics: Using robotics to motivate math, science, and engineering literacy in elementary school. International Journal of Engineering Education, 22(4), 711–722.
Chambers, J. (2015). Inside Singapore’s plans for robots in pre-schools. GovInsider.
Christie, J. F. (1990). Dramatic play: A context for meaningful engagements. The Reading Teacher, 43(8), 542–545.
Clements, D. H. (1999). Young children and technology. In G. D. Nelson (Ed.), Dialogue on early childhood science, mathematics, and technology education. Washington, DC: American Association for the Advancement of Science.
Cordes, C., & Miller, E. (2000). Fool’s gold: A critical look at computers in childhood. College Park, MD: Alliance for Childhood.
Digital News Asia. (2015, September 24). IDA launches S$1.5 m pilot to roll out tech toys for preschoolers. Retrieved from: https://www.digitalnewsasia.com/digital-economy/ida-launches-pilot-to-roll-out-tech-toys-for-preschoolers.
Fields, M. V., & Hillstead, D. V. (1990). Whole language in the play store. Childhood Education, 67(2), 73–76.
Hobbs, R. (2010). Digital and media literacy: A plan of action. The Aspen Institute.
Hollandsworth, R., Dowdy, L., & Donovan, J. (2011). Digital citizenship in K-12: It takes a village. TechTrends, 55(4), 37–47.
Jones, G. (2008). Killing Monsters: Why children need fantasy, superheroes, and make-believe violence. Basic Books.
Kazakoff, E., & Bers, M. (2012). Programming in a robotics context in the kindergarten classroom: The impact on sequencing skills. Journal of Educational Multimedia and Hypermedia, 21(4), 371–391.
Kuh, L. P. (Ed.). (2014). Thinking critically about environments for young children: Bridging theory and practice. New York, NY: Teachers College Press.
Lee, K., Sullivan, A., & Bers, M. U. (2013). Collaboration by design: Using robotics to foster social interaction in Kindergarten. Computers in the Schools, 30(3), 271–281.
Lerner, R. M., Lerner, J. V., Almerigi, J., Theokas, C., Phelps, E., Gestsdottir, S., et al. (2005). Positive youth development, participation in community youth development programs, and community contributions of fifth grade adolescents: Findings from the first wave of the 4-H study of positive youth development. Journal of Early Adolescence, 25(1), 17–71.
Lillard, A. (2005). The impact of movement on learning and cognition. In A. Lillard (Ed.), Montessori: The science behind the genius. New York, NY: Oxford University Press.
Maeda, J. (2012). STEM to STEAM: Art in K-12 is key to building a strong economy. Edutopia: What works. in education.
Maguth, B. (2012). In defense of the social studies: Social studies programs in STEM education. Social Studies Research and Practice, 7(2), 84.
Massachusetts Department of Education. (2006). Massachusetts science and technology/engineering curriculum framework. Retrieved from http://www.doe.mass.edu/frameworks/scitech/1006.pdf
Nicholson, S. (1972). The theory of loose parts, an important principle for design methodology. Studies in Design Education Craft & Technology, 4(2).
Oppenheimer, T. (2003). The flickering mind: Saving education from the false promise of technology. New York: Random House.
Papert, S. (1980). Mindstorms: Children, computers, and powerful ideas. Basic Books, Inc.
Perlman, R. (1976). Using computer technology to provide a creative learning environment for preschool children. Logo memo no 24, Cambridge, MA: MIT Artificial Intelligence Laboratory Publications 260.
Pomeroy, S. R. (2012). From STEM to STEAM: Science and art go hand-in-hand. Scientific American Guest Blog.
Resnick, M. (2006). Computer as paintbrush: Technology, play, and the creative society. Play = learning: How play motivates and enhances children’s cognitive and social-emotional growth, 192–208.
Resnick, M., Martin, F., Berg, R., Borovoy, R., Colella, V., Kramer, K., et al. (1998). Digital manipulatives. In Proceedings of the CHI ‘98 Conference, Los Angeles, April 1998.
Robelen, E. W. (2011). STEAM: Experts make case for adding arts to STEM. Education week, 31(13), 8.
Root-Bernstein, R. (2011). The art of scientific and technological innovations. Retrieved April, 13, 2011.
STEM to STEAM. (2016). Retrieved July 27, 2016, from http://stemtosteam.org/
Strong-Wilson, T., & Ellis, J. (2007). Children and place: Reggio Emilia’s environment as third teacher. Theory Into Practice, 46, 40–47.
Sullivan, A., & Bers, M. U. (2017). Dancing robots: Integrating art, music, and robotics in Singapore's early childhood centers. International Journal of Technology and Design Education. Online First.
Sullivan, A., & Bers, M. U. (2015). Robotics in the early childhood classroom: Learning outcomes from an 8-week robotics curriculum in pre-kindergarten through second grade. International Journal of Technology and Design Education. Online First.
Sullivan, A., Elkin, M., & Bers, M. U. (2015). KIBO Robot demo: Engaging young children in programming and engineering. In Proceedings of the 14th International Conference on Interaction Design and Children (IDC ‘15). ACM, Boston, MA, USA.
Sullivan, A., Kazakoff, E. R., & Bers, M. U. (2013). The wheels on the bot go round and round: Robotics curriculum in pre-kindergarten. Journal of Information Technology Education: Innovations in Practice, 12, 203–219.
U.K. Department for Education. (2013, September). National curriculum in England: Computing programmes of study. Statutory guidance. London, UK: Crown copyright.
U.S. Department of Education, Office of Educational Technology (2010). Transforming American education: Learning powered by technology. Washington, D.C. Retrieved from http://www.ed.gov/technology/netp-2010
White House. (2011). Educate to innovate. Retrieved from: http://www.whitehouse.gov/issues/education/educate-innovate
Wing, J. (2006). Computational thinking. Communications of the ACM, 49(3), 33–35.
Wyeth, P. (2008). How young children learn to program with sensor, action, and logic blocks. International Journal of the Learning Sciences, 17(4), 517–550.
Yakman, G. (2008). STEAM education: An overview of creating a model of integrative education. In Pupils’ Attitudes Towards Technology (PATT-19) Conference: Research on Technology, Innovation, Design & Engineering Teaching, Salt Lake City, Utah, USA.
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Sullivan, A., Strawhacker, A., Bers, M.U. (2017). Dancing, Drawing, and Dramatic Robots: Integrating Robotics and the Arts to Teach Foundational STEAM Concepts to Young Children. In: Khine, M. (eds) Robotics in STEM Education. Springer, Cham. https://doi.org/10.1007/978-3-319-57786-9_10
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