This thesis investigates digital implementation issues on spindle machine drives at high speed. The machine operating speed is designed beyond 30krpm where the ratio of drive sample frequency fsample over rotor electrical frequency fe is less than 5. Because digital microcontrollers are used in variable frequency machine drives to realize the field-oriented control (FOC), the discretized effects must be considered to maintain the controller stability at high speed under low ratios of fsample/fe. In this thesis, the machine current controller based on three continuous controller design and approximation methods are compared at low fsample/fe. It is shown that the linear approximation might be able to maintain the controller stability if the voltage delay and inductance cross-coupling are perfectly compensated. However, the closed-loop drive performance strongly dependents on the overall controller bandwidth and machine parameters. An 8-pole interior PM machine with a maximum speed at 32-kprm where fsample/fe = 4.7 is experimentally tested to compare the high speed performance among three controllers. This thesis includes the design guideline of PM spindle machine drive for high speed operation based on the simulation comparison of different machine characteristics.