The ability of structural elements to absorb input energy through inelastic deformation and supplemental damping is a primary factor in determining structural damage during earthquake excitation. This study proposes an energy methodology for the seismic evaluation of single-degree-of-freedom (SDOF) systems, considering the effect of fluid viscous dampers (FVDs). The FVD is characterized by supplemental damping ratio, [Formula: see text], and velocity power [Formula: see text]. A computer algorithm is developed for the numerical simulation of SDOF systems using nonlinear time history analysis, which is verified through a number of validation examples. This study focuses on issues related to input and hysteretic energies [Formula: see text] with particular emphasis on near-field records and their interrelationship with seismic response demand, which is defined as non-dimensional indices for SDOF systems without FVD and those equipped with FVD. The energy indices ([Formula: see text] and [Formula: see text]) are the ratios of input and hysteretic energies to maximum displacement demand, respectively. The results show that the natural period [Formula: see text], ductility level [Formula: see text], [Formula: see text], and [Formula: see text] have a significant effect in the determination of energy spectra [Formula: see text]. The non-dimensional [Formula: see text] is a more stable and reliable indicator than [Formula: see text] to quantify the damage potential of ground motion. Finally, the observations of the energy approach provided in this study indicate that it can be used as a useful tool for developing energy-based guidelines for structures incorporating FVDs.