Exact general solutions for the mode shapes of longitudinally vibrating non-uniform rods via Lie symmetries

Abstract

A Lie symmetry method-based approach is proposed for systematically computing general solutions in closed-form for the mode shape equation of non-uniform and unconventional vibrating rods. The mode shape equation is modeled by the elementary rod theory, addressing polynomial, exponential, trigonometric, and hyperbolic cross-section variations. The method provides algorithmic order-reduction steps for solving the investigated mode shape equation, producing a first-order Riccati equation whose integration reveals the aimed solutions for the problem. Illustrative examples are presented, including original solutions in closed-form as well as solutions previously obtained in the literature by other approaches. Mode shapes from general solutions with appropriate rod boundary conditions are also considered for different examples. • Original general solutions establish new exact mode shapes of non-uniform rods. • The Lie symmetry method allows addressing new cross-section variations systematically. • Mode shapes derive from the general solutions with rod boundary conditions. • Lie symmetry applications have been highlighted for further problems of interest.