Abstract Beam bending and torsional behavior are foundational to structural mechanics, forming the cornerstone of engineering analysis for slender structures across educational and research domains. Traditional instruction relies on small-deflection theory, which, while analytically convenient, can obscure critical aspects of real-world structural behavior. This study presents an integrated research and education initiative: the development of an interactive Graphical User Interface (GUI) application built on a nonlinear rod model to simulate cantilever beam mechanics--a canonical case in structural analysis education, whose framework also supports a broad range of research applications involving large deformations. The GUI enables real-time visualization and comparison of linear and nonlinear responses in both 2D and 3D, allowing users to examine the limitations of small-deflection assumptions and appreciate the broader applicability of nonlinear models. The tool builds on a previously established two-step initial value formulation for solving the nonlinear cantilever problem, ensuring efficient simulation. Its modular design allows customization, ranging from simple interfaces for basic education to advanced features for in-depth analysis, making it suitable for diverse learners and researchers. When deployed in an undergraduate aerospace structures course, the tool enabled students to explore when nonlinear modeling becomes essential and to examine small-deflection assumptions that might seem abstract. This interactive platform bridges the gap between analytical theory and real-world structural behavior, offering an intuitive educational experience and serving as a stepping stone for undergraduate engagement in large-deformation research, lowering the barrier to nonlinear computational modeling and advanced structural analysis.
Ahmed et al. (Thu,) studied this question.