The object of this study is to develop an optimal fractional-order proportional-integral-derivative (OFOPID) control strategy for controlling the mover position of a voice coil motor (VCM)-based x-y motion stage. First, the operating principle and dynamics of the VCM-based x-y motion stage are described. Then, a design of the fractional-order proportional-integral-derivative (FOPID) control is introduced on the basis of the fractional calculus. With the additional degree of freedom to the control system parameters, the FOPID control can improve the control responses and robustness of the conventional proportional-integral-derivative (PID) control. In order to improve the robustness of the system, a fuzzy fractional-order PD control is proposed based on fuzzy theory, which can solve jitter phenomenon of the traditional fractional-order PID. However, tuning these extra fractional operators increases the complexity of the control system design. In this regard, the FOPID controller is further proposed in which five interdependent control parameters including proportional gain, integral gain, derivative gain, fractional operator of integral, and fractional operator of derivative are all online optimally determined via an adaptive cuckoo search algorithm (ACSA). In the ACSA, the step size and discovery probability are dynamically adjusted to regulate the abilities of global and local searches. The summation of integral absolute errors in x and y axes of the VCM-based x-y motion stage during tracking process is chosen as a performance index for minimization. In this study, all of the control strategy were implemented via the digital signal processor (DSP). In addition, two reference trajectories and three control modes were provided to evaluate the control performances of different control systems. the experimental results can be verified that the designed controller can effectively control the voice coil motor positioning platform.