Special concentrically braced frame (SCBF) is one of the effective earthquake-resisting frames used in the high seismic area. Unlike the moment-resisting frame, inelastic deformation of the SCBF originates from the braces which are designed to yield in axial tension and to buckle, globally or locally, in axial compression. The brace forces are transferred to the beam and column through gusset plates. The purpose of this study is to establish the hysteretic behavior of H-shaped section bracing member and the gusset plate, and to investigate the strength and hysteresis. Nonlinear finite element analyses were conducted, and numerical models were established to research the inelastic hysteretic behavior of the brace and connection to gusset plate, considering three parameters: the ratio of tensile strength of the gusset plate to brace (βj), the length of the clearance (LC), and the effective width of the gusset plate (W). According to parametric study results, an experimental program was planned to carry out the cyclic loading test to explore the effect of gusset plate details on the hysteretic behavior. Six specimens were designed to consider the parameter of the type of clearance (LC/EC) in addition to the parameters used in the analysis. The results of the finite element analysis demonstrated that increasing the parameter βj resulted in the increase in overall buckling strength and energy dissipation of the brace. The parameter LC showed that the clearance length 2t provided adequate rotational capacity for the brace end. Increasing the gusset plate width (W) led to the decrease of the stress concentration at the gusset plate due to larger loaded area at the gusset plate, and to enhance slightly the overall buckling strength of the brace caused by the shorter brace length. The test results showed that all six specimens possessed stable nonlinear behavior and energy dissipation. The trapezoidal gusset plate (TGP) with linear or elliptic clearance could transfer stably the brace forces to the beam and column, and the hysteresis loop could reach 5 to 6% rad. of the interstory drift angle. The out-of-plane deformation (OOPD) of the brace reached to 15% of the brace length while the gusset plate could provide the OOPD of 2.5% of the brace length. However, the strength of the H-shaped brace deteriorated significantly after buckled. Four specimens with elliptic clearance revealed local cracking, but not brittle failure, at the gusset plate near the welding zone which also pointed out the possible stress concentration. The trapezoidal gusset plate developed in this study can possess the force transfer and rotational capacity for the brace end which have been demonstrated by the numerical model analysis and cyclic loading tests. The gusset plate can enhance the brace to stably dissipate energy exerted from earthquake excitation, by developing brace behavior of yielding in axial tension and buckling in axial compression. The proposed design parameters can be used for designing the gusset plate.