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중학교 과학 영재들의 공학 설계 과정에 대한 인식 조사 연구

A Study on Perceptions of Scientifically Gifted Middle School Students about Engineering Design Process

  • 투고 : 2017.07.24
  • 심사 : 2017.09.21
  • 발행 : 2017.10.31

초록

본 연구에서는 중학교 과학영재들의 성별과 재능영역에 따른 공학 설계 과정에 대한 인식을 조사하였다. 공학 설계 과정에 대한 인식 조사 도구는 문제 정의 능력, 정보 수집 및 활용 능력, 아이디어 도출 능력, 탐구 수행 능력, 협업능력(의사소통, 협동, 리더십) 등의 총 5개 영역으로 구성되어 있으며, 리커르트 5점 척도로 설문에 응답하도록 하였다. 연구 대상으로는 총 102명(남자 69명, 여자 33명)의 중학교 과학영재들이 설문 조사에 참여하였으며, 성별과 재능영역(물리학, 생명과학, 소프트웨어, 수학, 천문지질, 화학)에 따라 비교 분석하였다. 과학영재들은 자신의 공학 설계 과정에 대해 높은 수준의 인식을 갖고 있었다. 따라서 과학 영재들의 성별과 재능영역에 따라 관심분야의 영재성이 충분히 발휘될 수 있도록 공학 설계 과정을 반영한 맞춤형 영재 교육 프로그램의 개발이 필요하다. 또한 과학영재들의 실제적인 요구를 충분히 반영하여 과학 영재를 위한 공학 설계 프로그램의 교수 학습 방법 및 전략이 수립되어야 할 것이다.

The purpose of this study is to investigate the perceptions of scientifically gifted middle school students about their engineering design process according to gender and talent division. The instrument in surveying their perceptions about the engineering design process consists of 24 items (Likert 5 point type) five domains: problem definition, information collection and utilization, idea generation, inquiry performance, and teamwork (communication, cooperation, leadership). A total of 102 scientifically gifted students participated in the survey, according to gender (69 males and 33 females) and talent divisions (physics, biological sciences, software, mathematics, space-geological sciences, and chemistry). They had a high level of awareness of their engineering design ability. It is necessary to develop a customized gifted-education program so that their talent in their field of interest can be fully displayed according to the gender and talent division. In addition, the teaching and learning methods and strategies of the engineering design program for the scientifically gifted middle school students should be established to fully reflect the practical needs of the talented.

키워드

참고문헌

  1. Ahn, J., & Lim, J. (2014). The effects of team personality composition on team creativity in engineering design class. Journal of Engineering Education Research, 17(1), 50-56.
  2. Atman, C. J., Adams, R. S., Cardella, M. E., Turns, J., Mosborg, S., & Saleem, J. (2007). Engineering design processes: A comparison of students and expert practitioners. Journal of engineering education, 96(4), 359. https://doi.org/10.1002/j.2168-9830.2007.tb00945.x
  3. Campion, M. A., Medsker, G. J., & Higgs, A. C.(1993). Relationships between work group characteristics and effectiveness: A replication and extension. Personnel Psychology, 49(2), 429-452. https://doi.org/10.1111/j.1744-6570.1996.tb01806.x
  4. Cho, H., & Chung, K. (2006). The impact of underlying attributes of design team members on the group creativity. Journal of korean society of design science, 19(5), 43-54.
  5. Cho, K. (2015). Case study on engineering camp program involving engineering design activity and intra-/inter-team works for high school students: Plant factory as main theme. Journal of Engineering Education Research, 18(3), 46-58.
  6. Choi, J., Moon, Y., Shim, D., Yang, D., & Heo, Y. (2009). The influence of task conflict on project team performance: The moderating effect of team efficacy. Korean Management Review, 38(6), 1599-1623.
  7. Choi, Y., Park, K., Lim, Y., & Lim, B. (2011). A study on development and application effect of junior engineering team mission project education program and workbook. Journal of Engineering Education Research, 14(3), 15-24. https://doi.org/10.18108/jeer.2011.14.3.15
  8. Doppelt, Y., Schunn, C. D., Silk, E., Mehalik, M., Reynolds, B., & Ward, E.(2009). Evaluating the impact of a facilitated learning community approach to professional development on teacher practice and student achievement. Research in Science & Technological Education, 27(3), 339-354. https://doi.org/10.1080/02635140903166026
  9. Gallagher, J, & Gallagher, S. A. (1994). Teaching the gifted child. Boston, Allyn & Bacon.
  10. Guerra, L., Allen, D. T., Crawford, R. H., & Farmer, C. (2012). A unique approach to characterizing the engineering design process. In American Society for Engineering Education. American Society for Engineering Education.
  11. Hansen, J. B., & Feldhusen, J. F. (1994). Comparison of trained and untrained teachers of gifted students. Gifted Child Quarterly, 38(3), 115-121. https://doi.org/10.1177/001698629403800304
  12. Hong, E., Heo, N., & Lee, B. (2016). Investigation of 'Group Scientific Creativity' Factors in Gifted Students' Creative Project Solving Context. Journal of the Korean Association for Research in Science Education, 36(4), 527-538. https://doi.org/10.14697/jkase.2016.36.4.0527
  13. Hynes, M., Portsmore, M., Dare, E., Milto, E., Rogers, C., & Hammer, D. (2011). Infusing engineering design into high school STEM courses. Retrieved from http://ncete.org/flash/pdfs/Infusing%20Engineering%20Hynes.pdf.
  14. Kang, K., & Chung, C. (2012). The Perception of Scientifically Gifted Students of a University-Affiliated Gifted Education Center toward Its Educational Programs. Journal of the Korean Association for Research in Science Education, 20(1), 32(4). 751-759. https://doi.org/10.14697/jkase.2012.32.4.751
  15. Kim, E. (2010). Factors Influencing the Choice of Major for High Achievement Students in High School. Journal of Engineering Education Research, 13(6), 80-86. https://doi.org/10.18108/jeer.2010.13.6.80
  16. Kim, E., Lee, S., & Jeong, S. (2004). Characteristics and Improvement of Engineering Education Program for Highschool Students in University. Journal of Engineering Education Research, 7(4), 5-15.
  17. Kim, H., & Lee, Y. (2012). A Study on Core Competencies of Science-Gifted Students Based on Teachers' and Students' Perspectives. Journal of the Korean Association for Research in Science Education, 32(7), 1241-1250. https://doi.org/10.14697/jkase.2012.32.7.1241
  18. Kim, H., Kamg, N., Kim, M., Maeng, S., Park, J., Baek, Y., Son, J., Shim, K., Oh, P., Lee, K., Lee, B., Chung, E., Han, I., Ha, H., & Han, H. (2017). Basic Research for Next Generation Science Education Standards. Korea Foundation for the Advancement of Science & Creativity and the Ministry of Education. Research results report.
  19. Kim, K. (2014). Examples of Elementary and Secondary Engineering Education in Korea: Chungnam University Young Talent Technology Talent Center. Engineering education, 50(4), 48-53.
  20. Kim, S., & Paik, S. (2011). The Analysis of the Characteristics of Teaching Strategies of Teachers in Charge of Science-Gifted Middle School Students. Journal of the Korean Association for Research in Science Education, 31(2), 295-313.
  21. Kim, S., & Yoo, M. (2012). Comparison on the Vocational Values and the Science Career Orientation between Middle School Scientifically Gifted Students and Non-Gifted Students. Journal of the Korean Association for Research in Science Education, 32(7), 1222-1240. https://doi.org/10.14697/jkase.2012.32.7.1222
  22. Kim, Y., Huh, H., Lee, C., & Kim, K. (2013a). A study on Engineering Professionals' Recognition about Engineering Education in Primary and Secondary School. Korean Institute of Industrial Educations, 38(2), 136-155.
  23. Kim, Y., Huh, H., Lee, C., & Kim, K. (2013b). Analysis of Elementary and Secondary School Teachers' Recognition about Engineering Education in Elementary and Secondary School. Journal of Educational Technology, 16(5), 9-17.
  24. Kim, Y., Lee, C., & Kim, K. (2012). Objectives and Contents of 'Engineering Technology' Subject Education perceived by Engineering Professionals. The Korean Journal of Technology Education, 12(2), 221-249.
  25. Kwon, H., & Park, K. (2009). Engineering Design: A Facilitator for Science, Technology, Engineering, and Mathematics [STEM] Education. Journal of Science Education, 33(2), 207-220. https://doi.org/10.21796/jse.2009.33.2.207
  26. Lee, J., & Lha, M. (2012). Semantic Network Analysis of Science Gifted Middle School Students' Understanding of Fact, Hypothesis, Theory, Law, and Scientificness. Korean Association Of Business Education, 32(5), 823-840. https://doi.org/10.14697/jkase.2012.32.5.823
  27. Lee, S. (2015). The Impact of a Science & Engineering Integrated Curriculum on Technical High School Students' Science Attitudes. Master's Thesis. Korea National University of Education, Chung-Buk, Korea.
  28. Lim, J., Ryu, K., & Kim, B. (2017). An exploratory study on the direction of education and teacher competencies in the 4th industrial revolution. The Journal of Korean Education, 44(2), 5-32.
  29. Liu, S., & Lederman, N. G. (2002). Taiwanese Gifted Students 'View of Nature of Science'. School Science and Mathematics, 102(3), 114-123. https://doi.org/10.1111/j.1949-8594.2002.tb17905.x
  30. MOE(Ministry of Education) (2015). 2015 revised curriculum -Science-. Seoul: Ministry of Education.
  31. Moon, D. (2008). The Development of Pre-Engineering Educational Program Model Based on STEM Integration Approach. Journal of Engineering Education Research, 11(2), 90-101.
  32. NAE(National Academy of Engineering) (2010). Standards for K-12 Engineering Education?. Washington, D.C.: The National Academies Press.
  33. NRC(National Research Council) (2009). Engineering in K-12 education : Understanding the status and improving the prospects. Washington, DC : The National Academies.
  34. NRC(National Research Council) (2013). Next generation science standards. Washington, DC: The National Academies Press.
  35. Noh, H., & Choi, J. (2017). An Analysis of the Interpersonal Competence of Science-Gifted Students in School and Science-Gifted Education Institute. Journal of the Korean Association for Research in Science Education, 37(2), 383-393.
  36. Park, H., & Baek, Y. (2014). Content Standards for K-9 Engineering Education. Journal of Engineering Education Research, 17(4), 87-94. https://doi.org/10.18108/jeer.2014.17.4.87
  37. Park, H., Kim, Y., Noh, S., Jeong, J., Lee, E., Yu, E., Lee, D., Park, J., & Baek, Y. (2012). Developmental Study of Science Education Content Standards. Journal of the Korean Association for Research in Science Education, 32(4), 729-750. https://doi.org/10.14697/jkase.2012.32.4.729
  38. Park, S., & Kim, K. (2005). Analysis on the Relationship between Gifted Science Students' Thinking Style Types and Academic Achievement and Science Concepts. Journal of the Korean Association for Research in Science Education, 25(2), 307-320.
  39. Park, S., & Nam, H. (2008). Research on Engineering & Technology Education for Elementary School Student by using F1 in Schools Program. Journal of Engineering Education Research, 11(1), 83-98.
  40. Park, T. (2009). Status and direction of youth engineering education. Engineering education and technology transfer, 16(2), 39-42.
  41. Pirola-Merlo, A., & Mann, L. (2004). The relationship between individual creativity and team creativity: Aggregating across people and time. Journal of Organizational Behavior, 25(2), 235-257. https://doi.org/10.1002/job.240
  42. Reid, C., & Romanoff, B. (1997). Using multiple intelligence theory to identify gifted children. Educational Leadership, 55(1), 71-74.
  43. Renzulli, J. S. (2000). New Directions in Creativity: Mark A. Mansfield Center, CT, Creative Learning Press, Inc.
  44. Renzulli, J. S. (2002). Expanding the conception of giftedness to include cocognitive traits and to promote social capital. The Phi Delta Kappan, 84(1), 33-58. https://doi.org/10.1177/003172170208400109
  45. Robinson, A., Shore, B. M. & Enerson, D. (2007). Best Practices in Gifted Education. Waco, Texas : Purfock Press Inc.
  46. Schffner, M. F. & Newsome, D. W. (2001). Identity development of gifted female adolescents: The influence of career development, age, and life-long salience. The J. of Secondary Gifted Education, 14(4), 201-211.
  47. Shim, K., So, K., Kim, H., & Chang, N. (2001a). Study on the Interest in Science of Science Gifted / Talented Middle School Students 1 - Comparison between Gifted / Talented and General Students. Journal of the Korean Association for Research in Science Education, 21(1), 122-134.
  48. Shim, K., So, K., Kim, H., & Chang, N. (2001b). Study on the Interest in Science of Science Gifted / Talented Middle School Students 2 - By Gifted / Talented Division. Journal of the Korean Association for Research in Science Education, 21(1), 135-148.
  49. Shim, K., So, K., Kim, H., & Chang, N. (2003). Preference of Science Gifted/Talented and General Students for Study Course and Occupation. Biology Education, 31(4), 292-298.
  50. So, K., Shim, K., Lee, H & Chang, N. (2000). Study on Attitude of Science Gifted and Talented Middle School Students toward Science. Journal of the Korean Association for Research in Science Education, 20(1), 166-173.
  51. Son, S. (2007). K-12. Engineering education and technology transfer, 14(4), 7-9.
  52. Son, S. (2008). Introduction to the UK youth exploration program. Engineering education and technology transfer, 15(2), 16-19.
  53. Song, S., & Shim, K. (2012). Study on Perception of Science High School Students about Composing Laboratory Reports by Grade. Journal of Science Education, 36(2), 303-312. https://doi.org/10.21796/jse.2012.36.2.303
  54. Song, S., & Shim, K. (2015). An Analysis of Writing Characteristics of Scientifically Gifted Students about Biological Sciences. Journal of Science Education, 39(1), 88-98. https://doi.org/10.21796/jse.2015.39.1.88
  55. Song, S., & Shim, K. (2017). A Study on the Perception of Scientifically Gifted High School Students about Designing an Experiment and Discussing Activity. Biology Education, 45(1), 81-91.
  56. Song, S., Kil, J., & Shim, K. (2015). A Case Study on the Evaluation of Scientific Inquiry Ability of Elementary Scientifically Gifted Students : Observing and Inferring, Designing an Experiment, and Concluding. Journal of Science Education, 39(3), 376-388. https://doi.org/10.21796/jse.2015.39.3.376
  57. Sternberg, R. J., & Lubart, T. I. (1991). Creating creative minds. The Phi Delta Kappan, 72(8), 608-614.
  58. Sung, E., & Na, S. (2012). The Effects of the Integrated STEM Education on Science and Technology Subject Self-efficacy and Attitude toward Engineering in High School Students. The Korean Journal of Technology Education, 12(1), 255-274.
  59. UBS (2016). Extreme automation and connectivity: The global, regional, and investment implications of the Fourth Industrial Revolution. UBS White Paper for the World Economic Forum, Annual Meeting 2016.
  60. Van Tassel-Baska, J., Bass, G., Ries, R., Poland, D., & Avery, L. (1998). A national study of science curriculum effectiveness with high ability students. Gifted Child Quarterly, 42(4), 200-211. https://doi.org/10.1177/001698629804200404
  61. Woodman, R. W. & Schoenfeldt, L. F. (1990). An interactionist model of creative behavior. The Journal of Creative Behavior, 24(4), 279-290. https://doi.org/10.1002/j.2162-6057.1990.tb00549.x
  62. Yang, T., Bae, M., Han, G., & Park, I. (2003). Scientifically Gifted Students' Science Related Attitudes and Its Relationships with Intelligence and Science Process Skills. Journal of the Korean Association for Research in Science Education, 23(5), 531-543.