The demand of robot manipulator keeps increasing in the field of automation industry recently. However, due to lack of position accuracy, the usage of industrial robot has usually been limited to the process that requires less accuracy such as pick and place, spray painting, and drilling. The error sources of industrial robot are classified into two categories, the geometric error that comes from size tolerance or assembling error, and the non-geometric error composed of other errors caused by different operating conditions at joints or links, including backlash, hysteresis, compliance (or elastic), and thermal deformation. Some of traditional techniques require more information to estimate the torque applied to joints, which can be obtained by executing identification process with communication to joint motor or setting up F\T sensor with higher cost. The other traditional techniques could only identify parameters that represent the fusion of compliance parameter and link mass and center of gravity. This study presents an approach to the identification of geometric error, joint backlash, and compliance error simultaneously with positional measurements only, and the identified parameters are used to predict and compensate for the position error of the robot with different moving direction or attached payload. The proposed approach is based on modified Denavit-Hartenberg (MDH) model, firstly the backlash angles are calculated with the position difference of opposite rotating direction of each joint, and the compliance coefficients are identified by applying two kinds or more designed payloads, then the geometric error and the parameters consisting of link mass and center of gravity are formulated by a Levenberg-Marquardt algorithm combined with parameter selecting method. Compared to recent literatures, the proposed method shows more stability under random disturbance during numerical simulations. The proposed approach is applied to a 6 degree-of-freedom industrial serial robot HIWIN RT605-710, the experiment demonstrates that the maximum and mean position error can be improved by 61% and 84% with same payload condition, and the maximum and mean position error can be improved by 51% and 75% after changing payload condition.