The robust QFT (Quantitative feedback theory) control structure for improving bandwidth of the velocity loop for the AC servo motor has been studied in this Thesis. By using Nichols Chart of the motor system, the QFT controller can be obtained to effectively suppress the resonance peak. Experimental results indicate that the velocity bandwidth of the Shih-Lin AC servo motor can be thus enhanced from 613 Hz to 806 Hz with a resonance peak under 2 dB. As the load or the system gain significant changes, the original nominal model for the QFT design is not suitable anymore and a redesigning process with a newly identified system model is thus required in practice. By applying the additional 3.9 J load to the servo motor, the bandwidth can be thus enhanced from 93 Hz to 206 Hz with the newly designed QFT controller. Experimental results of the servo motor implemented on the DYNA CNC 1007 machine tool indicate that regardless of CNC motion command feedrate, the motion accuracy can be well maintained by implementing the QFT controller. Results also indicate that to eliminate the effect of external disturbances and command changes, the system compensated with both the DDOB and tuned position loop P controller will maintain the motion accuracy well.