The purpose of this study was to find the difference in pitching mechanics among various ages by comparing the kinematics, temporal and kinetics parameters. and investigate the relationship of biomechanical factors to baseball pitching velocity in each group. Ten pitchers of each level were served to be subjects (junior high school:67±12kg， 167±11cm；senior high school:74±9kg，179±5cm；college 88±10kg，179±7cm). Two forceplates (Kistler, 1000 Hz) and a 3-D motion capture system (Vicon MX13,200Hz) were used to collect kinetics and kinematics data. The subject threw to a target (40×60cm) which is 3 m in front of the force plates. Data from the 3 fastest successful trials were averaged for each subject. A one-way ANOVA was conducted for each parameter to identify differences among the three levels (junior, senior high school, college). Then 6 trails of each subject were chosen for regression analysis. Step-wise regression analysis was used to finding the relationship of biomechanical factors to baseball pitching velocity at each age level. The result showed the ball speed of the junior high school pitchers (JHP) was slower than senior high school (SHP) and college pitchers (CP), and no difference existed in SHP and CP. At kinematic and temporal parameters, the JHP had more shoulder rotation range of angleand longer arm acceleration phase than the other two groups. The SHP had less lead legknee flexion at lead foot contact ground, more elbow extension and shoulder rotation velocity at arm acceleration time. In addition, their peak shoulder external rotation angle appeared later, and the arm acceleration phase time was shorter. At upper limbs kinetic parameters, the peak elbow varus moment, peak shoulder internal rotation moment, peak elbow axis force, and peak shoulder poster force of JHP are lower than other two groups. At pivot foot kinetic parameters, the peak axis force in the three joints, hip adduction moment, ankle and knee flexion moments were existed a tendency to increase with age. At lead foot kinetic parameters, the ground reaction force and the axis force of knee and ankle increase with age, but no difference existed in the hip joint. In JHP group, 3 biomechanical factors were associated with ball velocity. They were peak shoulder internal rotation moment in arm cocking phase, stride length, and elbow peak flexion angle. In SHP group, 4 biomechanical factors were associated with ball velocity. They were shoulder internal rotation moment in arm cocking phase, lead foot knee flexion angle at ball release, peak upper trunk angular velocity and body hight. In CP group, 4 biomechanical factors were associated with ball velocity. They were peak shoulder internal rotation moment in arm cocking phase, peak lead foot knee flexion angle at foot contact, peak shoulder external rotation angle and peak elbow extension angular velocity. . As the result showed, the pitching mechanics kinematics of JHP are similar with other two groups. They have smallest upper and lower limbs kinetics. From JHP to SHP, ball velocity, body hight, upper limbs joint angular velocity, upper and lower limbs kinetics all increased. From SHP to CP, body mass and, lower limbs kinetics increased, but ball speed and upper limbs kinetics show no difference. The upper limbs kinetics was an important biomechanical factors associated with ball velocity in all three groups. We believe that the insufficiency of upperlimbs kinetic of CP cause their ball velocity similar with SHP.