Asymptotic Properties of Solutions to Fourth-Order Difference Equations on Time Scales

We provide sufficient criteria for the existence of solutions for fourth-order nonlinear dynamic equations on time scales (a(t)xΔ2(t))Δ2=b(t)f(x(t))+c(t), {\left( {a\left( t \right){x^{{\Delta ^2}}}\left( t \right)} \right)^{{\Delta ^2}}} = b\left( t \right)f\left( {x\left( t \right)} \right) + c\left( t \right), such that for a given function y : 𝕋 → ℝ there exists a solution x : 𝕋 → ℝ to considered equation with asymptotic behaviour x(t)=y(t)+o(1tβ) x\left( t \right) = y\left( t \right) + o\left( {{1 \over {{t^\beta }}}} \right) . The presented result is applied to the study of solutions to the classical Euler–Bernoulli beam equation, which means that it covers the case 𝕋 = ℝ.