The present study aims at uncovering Mathematical Concept Understanding Ability in solving the problem of 3D Geometry from the perspective of both cognitive styles dependent and independent field. As the instrument, this study adopts Group Embedded Figure Test, Observation worksheet, test, interview, and documentation. In dealing with data analysis, it relies on qualitative analysis consisting data reduction, data display, and conclusion drawing. Based on the investigation, it could be inferred that the students with cognitive dependent field could solve the problem with 3D Geometry; however, they still need some improvements to realize a proper way in using such method. On the other hand, the students with cognitive independent field, they could correctly operationalize the 3D Geometry concept to solve the same problem. In addition, this study also recommends that to minimize the problem above, the teacher is supposed to give proportional distribution in implementing either individual or group task.

Agoestanto, A., Sukestiyarno, Y., & Rochmad. (2016). Analysis of Mathematics Critical Thinking Students in Junior High School Based on Cognitive Style. Journal of Physics: Conf. Series, 824(012052), 1–8. https://doi.org/10.1088/1742-6596/755/1/011001

Ali, A. A., & Reid, N. (2012). Understanding Mathematics : Some Key Factors. European Journal of Educational Research, 1(3), 283–299.

Azlina, N., Amin, S. M., & Lukito, A. (2018). Creativity of Field-dependent and Field-independent Students in Posing Mathematical Problems. Journal of Physics: Conf. Series, 947(012031), 1–6.

Hidayat, R., & Siswono, T. Y. E. (2016). Profil Berpikir Siswa Smp Dalam Problem Posing Berdasarkan Gaya Kognitif Field Dependent-Field Independent. Mathedunesa, 3(5), 473–482.

IAE. (1999). TIMSS 1999 User Guide for the International. Boston: International Study Center Lynch School of Education Boston College.

IAE. (2004). TIMSS 2003 International Mathematics Report. Boston: TIMSS & PIRLS International Study Center.

IEA. (2008). TIMSS 2007 International Mathematics Report: Findings from IAE's Trend in International Mathematics and Science Study at the Fourth and Eighth Grades. Boston: TIMSS & PIRLS Internation Study Center.

IEA. (2011). TIMSS 2011 International Results in Mathematics. Boston: TIMSS & PIRLS International Study Center.

IAE. (2015). TIMSS 2015 International Results in Mathematics: Fourth Grades Mathematics. Boston: TIMSS & PIRLS International Study Center.

Karaçam, S. (2015). The effects of field dependent / field independent cognitive styles and motivational styles on students ’ conceptual understanding about direct current circuits. Asia-Pacific Forum on Science Learning and Teaching, 16(2), 1–19.

Minarni, A., Napitupulu, E. E., & Husein, R. (2016). Mathematical Understanding And Representation Ability Of Public Junior High School In North Sumatra. Journal on Mathematics Education, 7(1), 43–56.

NCTM. (2000). Principles and standards for school mathematics. Reston, VA.: National Council of Teachers of Mathematics.

Nuriadin, I., Kusumah, Y. S., Sabandar, J., & Dahlan, J. A. (2015). Enhancing Of Students’ Mathematical Reflective Thinking Ability Through Knowledge Sharing Learning Strategy In Senior High. International Journal of Education and Research, 3(9), 255–268.

Onyekuru, B. U. (2015). Field Dependence-Field Independence Cognitive Style, Gender, Career Choice and Academic Achievement of Secondary School Students in Emohua Local Government Area of Rivers State. Journal of Education and Practice, 6(10), 76–86.

OECD. (2000). Measuring Student Knowledge and Skills: The PISA 2000 Assessment of Reading, Mathematical. Paris: OECD.

OECD. (2003). First Results from PISA 2003. Paris: PISA Publications.

OECD. (2006). PISA 2006 Technical Report. Paris: OECD Publishing.

OECD. (2012). PISA 2012 Results in Focus: What 15year-olds Know and What They Can Do with What They Know. New York: Columbia University.

OECD. (2016). PISA 2015 Results in Focus. New York: Columbia University.

Purnomo, R. C., Sunardi, & Sugiarti, T. (2017). Profil Kreativitas dalam Pemecahan Masalah Matematika Ditinjau dari Gaya Kognitif Field Independent ( FI ) dan Field Dependent ( FD ) Siswa Kelas VIII A SMP Negeri 12 Jember. Jurnal Edukasi, 4(2), 9–14.

Riding, R. J., & Sadler-smith, E. (1997). Cognitive style and learning strategies : some implications for training design. International Journal of Training and Development, 1(3), 199–208.

Sudirman. (2016). Analisis pemahaman konsep himpunan mahasiswa ditinjau dari asal sekolah. Mathline: Jurnal Matematika Dan Pendidikan Matematika, 1(1), 43–52.

Sumartini, T. S., & Priatna, N. (2018). Identify student mathematical understanding ability through direct learning model. Journal of Physics: Conference Series PAPER, 1132(012043), 1–8. https://doi.org/10.1088/1742-6596/1132/1/012043

Waedi, Winarso, W., & Izzati, N. (2017). Perbandingan Pemahaman Konsep Matematika Siswa Ditinjau dari Gaya Kognitif antara Field Independent dengan Field Dependent. Eduma: Jurnal Pendidikan Dan Pembelajaran Matematika, 6(1), 1–7.

Witkin, H. A., Moore, C. A., Goodenough, D., & Cox, P. W. (1977). Field-Dependent and Field-Independent Cognitive Styles and Their Educational Implications. Review of Educational Research, 47(1), 1–64. https://doi.org/10.3102/00346543047001001

Wijayanti, An., Safitri, P. T., & Raditya, A. (2018). Analisis Pemahaman Konsep Limit Ditinjau Dari Gaya Belajar Interpersonal. Prima: Jurnal Pendidikan Matematika, 2(2), 157–173.

Wulandari, R. (2017). Analisis Gaya Kognitif Siswa Dalam Pemecahan Masalah Matematika di SDN Banyuajuh I Kamal Madura. Widyagogik, 4(2), 95-106.