This paper presents a finite element methodology for the static analysis of
infinite periodic structures under arbitrary loads. The technique hinges o
n the method of representative cell which through the discrete Fourier tran
sform reduces the original problem to a boundary value problem defined over
one module, the representative cell. Starting from the weak form of the tr
ansformed problem, or from the FE equations of the infinite structure, the
equilibrium equations are written in terms of the complex-valued displaceme
nt transforms which are considered as the displacements in the representati
ve cell. Having found the displacements in the transformed domain, the real
displacements anywhere in the real structure are obtained by numerical int
egration of the inverse transform. The theory, which is valid for spatial s
tructures with 1D up to 3D translational symmetry, is illustrated with exam
ples of periodic structures having 1D translational symmetry under general
static loading.