Euler-Bernoulli beams from a symmetry standpoint-characterization of equivalent equations

TL;DR

This paper completely classifies Euler-Bernoulli beam equations using Lie symmetry analysis, identifying equivalence classes based on symmetry Lie algebras and providing transformations to simplified representative equations.

Contribution

It offers a full symmetry-based classification of Euler-Bernoulli equations, characterizing physical parameters and constructing explicit transformations for each class.

Findings

Classified Euler-Bernoulli equations into symmetry-based equivalence classes.

Derived explicit transformations mapping complex equations to simple representatives.

Identified conditions under which non-uniform beams are equivalent to uniform beams.

Abstract

We completely solve the equivalence problem for Euler-Bernoulli equation using Lie symmetry analysis. We show that the quotient of the symmetry Lie algebra of the Bernoulli equation by the infinite-dimensional Lie algebra spanned by solution symmetries is a representation of one of the following Lie algebras: $2A_1$, $A_1\oplus A_2$, $3A_1$, or $A_{3,3}\oplus A_1$. Each quotient symmetry Lie algebra determines an equivalence class of Euler-Bernoulli equations. Save for the generic case corresponding to arbitrary lineal mass density and flexural rigidity, we characterize the elements of each class by giving a determined set of differential equations satisfied by physical parameters (lineal mass density and flexural rigidity). For each class, we provide a simple representative and we explicitly construct transformations that maps a class member to its representative. The maximally symmetric class described by the four-dimensional quotient symmetry Lie algebra $A_{3,3}\oplus A_1$ corresponds to Euler-Bernoulli equations homeomorphic to the uniform one (constant lineal mass density and flexural rigidity) . We rigorously derive some non-trivial and non-uniform Euler-Bernoulli equations reducible to the uniform unit beam. Our models extend and emphasize the symmetry flavor of Gottlieb's iso-spectral beams (Proceedings of the Royal Society London A 413 (1987) 235-250)