Continuing the study of VAFFS in which liquid crystals with positive anisotropy were used in 2D VAFFS to achieve fast response time, liquid crystals with negative anisotropy have also been used in 3D VAFFS to reach higher transmittance. However, in the case of 3D VAFFS, a two-step process may occur after we lengthen the applied voltage period. As a result, the virtual wall can disappear that makes response speed slower. In the previous study, it has been found by changing the pattern design of electrode we could extend the existence of virtual walls. This finding not only has high transmittance but also improves the effect of two-step process and explains the mechanism in it. This paper proposes the idea of limiting the applied voltage period. We hope there will be enough time to apply voltage, to drive the liquid crystal to reach high transmittance, and to return the voltage to zero before a two-step process occurs. In this way, we can obtain good transmittance, fast response time, and reduce the electrode size to reach faster response time. 3D VAFFS_com design is to add a whole piece of common electrode at the top. It will add vertical electric field to the existing horizontal electric fields. In addition to using liquid crystals with negative anisotropy in simulations, we here also use liquid crystals with positive anisotropy. These two designs can have completely opposite effect that can help us understand more about the design of 3D VAFFS_com.