Dynamic characteristics of complicated structures are greatly affected by various joints where the components are connected with each other. However, the joints are very difficult to model adequately and accurately. The parameter identification procedures of the joints are numerically complicated, ill-conditioned, and very sensitive to noise. Genetic Algorithm (GA), which imitates the evolution of nature, seems a very promising means in dealing with these identification problems. In this paper, the parameter identification procedure is carried out by implementing the Genetic Algorithm (GA), and using the Frequency Response Function (FRF) of the structure in the objective functions. First, the joint stiffness parameters of translation and rotation are identified using the natural frequency information and compared with those identified by substructure synthesis method. Damping parameters of the joint, then, are identified by using amplitudes and phase angles of FRFs. The identification of the joint parameters of a cantilever beam bolted at one end is conducted in this paper. The results show that the accuracy of identification increases if more FRFs information is used in the objective functions of the identification procedure. A two-stage strategy of defining search regions is used in this paper to promote the accuracy of the identified parameters.