Two types of displacement-dependent seismic damping devices, namely the ductile brace and friction damper based respectively on the buckling and friction mechanisms are proposed in this study. The ductile brace utilizes the yielding of pre-bent steel strips in geometrically large lateral deformation under axial loads to dissipate energy. The mechanical behavior and energy-dissipative characteristic of the pre-bent strips have been explored via a series of theoretical development, parametric study and component tests. Experimental results indicate a displacement-dependent but rate-independent energy-dissipative characteristic of the device. Encouraging seismic performance test results by shaking table tests suggest effectiveness and potential of the ductile braces as seismic structural dampers. On the other hand, the use of some special alloy as the core for both the friction damping brace and seismic friction wall has also been developed. The rate-independent energy-dissipative characteristics of the proposed friction dampers have been sufficiently realized via a series of component tests. Results indicate that the proposed alloy-based friction dampers possess stable and rich hysteresis loops with characteristics of the Coulomb’s friction mechanism. The special alloy presents high frictional coefficient of μ>0.7 that is much higher than those for the existing friction dampers. As a result, the capacity of the friction damper can be significantly enhanced. Moreover, the torque coefficient of the bolts has been calibrated experimentally. Results indicate that the torque coefficients of the bolts are diameter-dependent whereas the torque-to-normal force ratio remains constant, regardless of the bolt diameter.