Perspectives on Defining Engineering Leadership

Perspectives on Defining Engineering Leadership

Robyn Paul and Lynne Cowe Falls

Engineers are no longer only involved with the technical project details, but must also understand the broader picture as they are often acting as team leaders [1]. Consequently, there is a need to educate engineers not just in physics and mathematics, but also in many non-technical areas, including globalization, communication, and leadership [2]. This is being recognized worldwide, including in the second edition of “Rethinking Engineering Education”, where an extension was added to the CDIO Syllabus for Leadership [3].

One of the difficulties in the field of engineering leadership education is the need to clearly define engineering leadership and the skills required to be a leader in engineering [4]. A stronger understanding of these terms will help institutions to develop and improve engineering leadership education programs and to achieve the CDIO Syllabus for Leadership.

Leadership has been studied since the beginning of civilization, and there are many definitions and theories of leadership that have evolved over time. However, only recently has the term engineering leadership been introduced. The aim of this research is to answer the following: from the perspective of engineering students, academics, and professionals, what is engineering leadership and what skills are required to be a leader in engineering?

Engineering students, professionals, and academics are to be surveyed to understand their perspective on engineering leadership and the skills required to be a leader in engineering. Approximately 30 participants from each population will be recruited, a sample size based on John Creswell’s recommendations for grounded theory [5]. The survey responses will be coded using the qualitative constant comparative method as outlined by Glaser [6]. Proximity analysis will then be used to compare the resulting definition themes and skills to the original data, providing an overview of the themes and skills that are frequently used together.

The resulting definitions and skills from the different populations will provide insight to the variances in perspectives. The findings are expected to help to develop and improve engineering leadership education programs by setting a baseline for the programs. As well, the identified skills of engineering leaders will provide specific examples of program activities that will teach leadership skills and provide guidance to measurable program outcomes.

[1] Kumar, S., & Hsiao, J. K. (2007). Engineers learn “soft skills the hard way”: Planting a seed of leadership in engineering classes. Leadership and Management in Engineering, 7(1), 18-23. [2] Galloway, P. D. (Ed.). (2007). The 21st-century engineer: A proposal for engineering education reform. ASCE Publications. [3] Crawley E.F., Malmqvist, J., Ostlund, S., Brodeur, D.R., & Edstrom, K. (2014) Rethinking Engineering Education (2nd ed.). Springer. [4] Ahn, B., Cox, M., London, J., Cekic, O., & Zhu, J. (2014). Creating an Instrument to Measure Leadership, Change, and Synthesis in Engineering Undergraduates. Journal of Engineering Education, 103(1), 115-136. [5] Creswell, J. (1998). Qualitative inquiry and research design: Choosing among five traditions. Thousand Oaks, CA: Sage. [6] Glaser, B. (1978). Theoretical Sensitivity: Advances in methodology of grounded theory. Mill Valley, CA: Sociology Press.

Proceedings of the 11th International CDIO Conference, Chengdu, China, June 8-11 2015

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