Crosstalk is a major factor affecting the quality of 3D stereoscopic images. High levels of crosstalk may cause visual fatigue and mental and physical discomforts. Current 3D stereoscopic optics is created based on past designs and simulation results of optical software. Using conservative design parameters not only makes the design quality difficult to control but also wastes time and costs. Creating a predictive optical simulation model is necessary to solve the optimization problem in parameter designs, thereby ensuring image quality and manufacturing efficiency. This research aims to build an optimization module for optics design parameters to improve the quality of naked-eye 3D stereoscopic images. The proposed module applies back-propagation of artificial neural network to construct a model for crosstalk prediction in naked-eye 3D stereoscopic images. The performance of the model was evaluated by using simulated design parameters as input parameters and binocular luminance as target output value. Simulation results were then utilized for network training and testing. The difference of the deduction value of the prediction model and the target value. Take the predictive value of the artificial neural prediction model as the observed value of the Taguchi method; we can determine the combination of the optimal factors, by using the signal-to-noise ratio from the smaller-the-better response of the Taguchi method. This study utilized the optimal factor combination as the design basis and the microlenticular lens as an example to verify the combination of nanoimprint technology process. The Confocal 3D laser microscopy was used to measure the molds that results show that the geometric shape of the produced microlenticular lens is close to the design values, in which the geometric error is less than 5%. The surface roughness reaches the optical specular level, and the replication rate reaches 95%. Therefore, this process can produce single curvature, gap-free, long, flat, and high-precision microlens arrays. The optimization module can lower the post-processing crosstalk quality requirement effectively. The optimization module for optics design parameters can effectively and quickly obtain the best design parameter combination and reduce the quality requirement of interlaced blur image after processing.