This paper aims to design bracing members to achieve in-plane buckling of the braces while subjected to compression, and to study the strength and hysteretic behavior. The ways to lead the brace buckle in-plane are either reducing brace section at both ends of the brace to form a hinge, or using a connecting plate between the gusset plate and the brace to create a rotational area to buckle the brace in-plane. Finite element analysis was conducted to establish the numerical model for parametric study. On the basis of the analytical results, six specimens were designed and tested to validate the hysteretic behavior of the specimens. The results of the finite element analysis indicate that for the brace with reducing brace section and a single gusset plate the formation of the plastic hinge is not distinct because of the distinguish local deformation of the brace web to which the gusset plate was welded; however, the local deformation of the brace web can be attenuated by adding stiffeners. The brace with reducing brace section and double gusset plate can form expected hinge at both ends of the brace. Among the design variables, the depth of the reducing section has major effect of the strength and local behavior of the brace, while the width of the reducing section has minor effect. The brace designed to have connecting plate can achieve in-plane buckling; however the stress concentration occurred at the connection between brace and connecting plate may cause the failure of the brace. The test results demonstrated that all six specimens attained stable nonlinear behavior and dissipating energy. Four specimens with reducing section achieved 4 to 5% rad of the interstory drift angle, buckled in-plane, and fractured at the middle of the brace as predicted in the analysis. One specimen behaved premature failure of the fracture due to the crack occurred at the middle of the brace because of the less reducing section causing higher stiffness at the brace ends and large deformation at brace middle part. Moreover, the braces in-plane deformation of the brace with double gusset plate is larger than those with single gusset plate. The test results revealed that one of the specimens with connecting plate fractured at the connecting plate owing to the direct force transferring between gusset plates and brace flanges, losing the concept of the effective width of the connecting plate. The other specimens with connecting plate failed due to fracture occurred at the weld between the brace and connecting plate, causing by the weld defect. In summary, the brace designed by reducing section at both ends can achieve in-plane buckling of the brace, possesses typical inelastic behavior, and dissipate energy.