Catalytic activity of hydrogen evolution reaction (HER) in acidic media can be well predicted through hydrogen-adsorption free energy (∆GH*) previously. In the present study, we further develop a simple and useful method to diagnose the more complicated HER in alkaline media by utilizing three vital parameters of ∆GH*, hydroxide-adsorption free energy (∆GoH*), and activation energy of water dissociation (Ea(water)) in a radar chart. First, we examined single metals of Ag, Au, Co, Cu, Ni, Pd, Pt with the same crystal structure (FCC) and surface facet (111). The area of radar chart well correlated with the (logarithm of) exchange current density (log i0) from experiments, indicating the accuracy of our new method. Further, we examined Pt and Pd-based bimetallic catalysts of Pt3M, PtM, Pd3M and PdM (M = Ag, Au, Co, Ni, Pt, Pd, Rh, Ru). Excellent correlation is also found between the area and work function, representing as activity. Pt-based bimetals shows better activity than Pd-based one and Pt3Au shows the best HER activity. Finally, Fe3O4(220) and FeP(111) have been examined to extend our method in non-metallic catalysts. The predicted activity follow the trends of FeP(111) > Fe3O4(220), which consistent with the experiments that phosphides are more active than oxides.