Current seismic design and evaluation of bridges tends towards the well-known displacement coefficient method. Early displacement coefficients were statistically obtained through nonlinear time history analysis using polygonal hysteretic models. The displacement coefficient allows maximum inelastic displacement to be estimated from its maximum elastic displacement. Though it seems simple and convenience, most of the displacement coefficient method cannot necessary fit the test, as we know the real hysteresis behaviors of reinforced concrete bridge columns should be smooth rather than piecewise linear with abrupt stiffness changes. Also, the user couldn’t know the actual damage condition about the column under calculated displacement. For refining these shortcomings of displacement coefficient method, previous research proposed an innovative seismic evaluation method for reinforced concrete bridges called the Capacity-based inelastic displacement spectra. The inelastic displacement spectra associated with corresponding damage index for RC bridge columns were constructed through a series of nonlinear time history analysis of SDOF system using a smooth hysteresis model that can realistically simulate the seismic behaviors of reinforced concrete bridge columns including stiffness degradation, strength deterioration, pinching effect and path dependence with the effects of various design parameters and earthquake types In addition, it was demonstrated that the damage index can be used to accurately predict the onset of strength deterioration and also can be a good indicator for assessing the actual visible damage conditions of RC bridge column regardless of its loading history. Therefore, seismic analysis via this capacity-based inelastic displacement spectra can obtain not only the maximum responses of a column but also its damage condition under a given ground motion, providing a better insight into its seismic performance. In order to make the application of capacity-based inelastic displacement spectra more extensive, bridge column test results and failure photos that can cover practical design are needed. Therefore, this study designed five rectangular RC bridge columns for cyclic loading tests covering different longitudinal steel ratio and aspect ratio complied with current Taiwan seismic design codes and circular RC bridge columns test designed in previous research. For each of the tested columns, in addition to the basic cross-sectional analysis, failure observation, displacement distribution and strain gauge analysis, this study specifically identified the smooth hysteresis model parameters capable of representing different deterioration characteristic of structure properties. Furthermore, the cause of difference between the identified model parameters from variable design parameters of RC bridge columns were also discuss theoretically in this study. Finally, the database of capacity-based inelastic displacement spectra were constructed for each tested bridge columns in this study with their model identification results and corresponding damage state.