This study presents experimental and analytical results of post-tensioned precast concrete segmental bridge columns using energy-dissipating (ED) bars. Three ungrouted post-tensioned, prescast concrete-filled tube segmental bridge column specimens were designed and tested. All specimens were composed of a load stub, a footing, and four circular segments post-tensioned with internal unbonded high-strength strands. Moreover, Specimen 2 had four ED bars anchored between the first segment and footing, and Specimen 3 had four ED bars anchored between the second segment and footing. The effects of different anchoring position on segment opening and energy dissipation could be examined. In all specimens, the ratio of ED bar area to cross-sectional area of the segment, , was 0.66%. A correlation study was conducted on the test specimens using the computer program PISA 3D. The objective of the analysis was to perform a parametric study on 24 post-tensioned bridge columns, verifying the effects of the ED bar area, initial strand force, and column height-width ratio on the cyclic behavior. The test results showed that (1) the ED bar could increase energy dissipation in the hysteresis response, and Specimens 1-3 had the equivalent viscous damping ratio of 6.5-8.8%, and (2) plastic hinge length in the first or second segments varied with anchoring position of ED bars and lateral displacement. The parametric study showed that when the bridge column had =1.2%, the equivalent viscous damping ratio was increased to 12% with zero residual drift. When the bridge column had =2.4%, the equivalent viscous damping ratio was 14.8%, and the bridge column showed residual drift of 3.12% after reaching 6% peak drift. A design procedure was proposed based on the experimental and analytical studies.