The purpose of this study was to 1) quantify the change of momentum in the upper extremity during the tennis volley; 2) investigate the effects of the backhand volley technique and hand drive type on musculature behavior. Six male tennis players (mean age 26.5 ± 9.4 yrs; height 173.3 + 3.8 cm; weight 67.3 + 11.0 kg) with right hand dominant were recruited for this study. The six-camera HiRES Expert Vision motion system (Motion Analysis Corp., Santa Rosa, CA, USA) was used to collect the motion data of the upper extremity and the trunk. The electromyography (EMG) data war collected using MA-300, (Motion Lab Systems, Inc., USA) The tennis volley was two volley techniques, punch and drop for backhand drive, and the sampling rate was 240 Hz. Ten trials were collected for each technique and drive type for each subject. Each trial lasted for 8 seconds with a 3-minute rest between trials. A custom biomechanical model of the upper extremity was used to compute the three-dimensional (3D) momentum of the trunk and upper extremity. The results showed that the larger angular momentum in the punch volley may indicate that it required greater rotatory momentum to return the ball than the drop volley. In the drop volley, the linear and angular momentum decreased before ball impact; it therefore, in order to change the ball momentum and velocity after the stroke, players have to increase the period of ball impact. In the EMG analysis, the flexor carpi radialis and triceps brachii were most active among all muscles in the acceleration phase. The extensor carpi radilis was more active than the flexor carpi radialis, which shows that the extension and abduction in the wrist joint is helpful for keeping the wrist stable. Understanding the 3D biomechanical behavior of the upper extremity during different types of tennis volleys could allow tennis players and coaches to improve the players performance and prevent injury. It is also helpful for physicians and therapists in the diagnosis of sports injury and clinical treatment.