The advancement of photonic technologies increasingly relies on the integration of mechanically responsive elements, such as nanobeams, waveguide membranes, and microresonators, within optical circuits. These components often exhibit structural flexibility, where even minor mechanical oscillations can significantly influence optical behavior—particularly in nanoscale environments. Accurate modeling of such dynamic interactions is essential for the design and stability of nanophotonic and optomechanical devices. A fundamental mathematical model widely employed for analyzing such systems is the Euler–Bernoulli beam equation, which describes the bending and vibrational behavior of slender beams. The present study proposes a spline-in-tension tenchnique, designed to effectively capture the dynamic response of beam-like elements within structured optical systems.