Twist angle effects on the dynamic response of in-plane-switching liquid crystal displays

TL;DR

This paper analyzes how the twist angle affects the response time of in-plane-switching liquid crystal displays and proposes a symmetric device configuration that significantly improves response speed.

Contribution

It introduces a symmetric boundary configuration that reduces response time at least fourfold compared to conventional in-plane-switching modes.

Findings

Response time improved at least 4X

Symmetric boundary configuration enhances performance

Analytical results support the proposed design

Abstract

Twist angle effect on the response time of in-plane-switching liquid crystal displays are analyzed. We propose a device configuration whose top and bottom boundary liquid crystal layers are symmetric to each other with respect to the electric field direction. The analytical results of this device configuration indicate that the response time is improved at least 4X faster than that of a conventional in-plane-switching twisted-nematic mode and normal in-plane-switching mode.