Driving Waveform Design of Electrophoretic Display Based on Optimized Particle Activation for a Rapid Response Speed.

Wenyao He,Linwei Liu,Li Wang,Zhenyu Huang,Shitao Shen,Guofu Zhou,Zichuan Yi,Taiyuan Zhang,Wei Li,Chongfu Zhang,Lingling Shui

doi:10.3390/mi11050498

Abstract

Electrophoretic displays (EPDs) have excellent paper-like display features, but their response speed is as long as hundreds of milliseconds. This is particularly important when optimizing the driving waveform for improving the response speed. Hence, a driving waveform design based on the optimization of particle activation was proposed by analyzing the electrophoresis performance of particles in EPD pixels. The particle activation in the driving waveform was divided into two phases: the improving particle activity phase and the uniform reference grayscale phase. First, according to the motion characteristics of particles in improving the particle activity phase, the real-time EPD brightness value can be obtained by an optical testing device. Secondly, the derivative of the EPD brightness curve was used to obtain the inflection point, and the inflection point was used as the duration of improving particle activity phase. Thirdly, the brightness curve of the uniform reference grayscale phase was studied to set the driving duration for obtaining a white reference grayscale. Finally, a set of four-level grayscale driving waveform was designed and validated in a commercial E-ink EPD. The experimental results showed that the proposed driving waveform can cause a reduction by 180 ms in improving particle activity phase and 120 ms in uniform reference grayscale phase effectively, and a unified reference grayscale can be achieved in uniform reference grayscale phase at the same time.

Highlights

Electrophoretic display (EPD) technology has been a research topic of interest for many years due to its wide market potential [1]
As a paper-like display technology, EPDs have the advantages of paper-like display effect, ultra-low power consumption, and being readable under bright light [2,3]
EPDs have been widely used in e-books, electronic labels, and smart watches, amongst others [4,5]

Summary

Introduction

Electrophoretic display (EPD) technology has been a research topic of interest for many years due to its wide market potential [1]. It is of great significance to improve the response speed and reduce visibility of the ghost image of EPDs by optimizing the driving waveform design [6]. The particle activation phase is longer than the other two phases and has a significant impact on the response speed of EPDs. In order to optimize the activation phase, the particle activation can be optimized by a high-frequency voltage mode, but it is difficult to obtain a stable reference grayscale and the driving duration can reach 960 ms [14]. Some scholars have removed the particle activation phase and added a response latency to eliminate the original image, but the reference grayscale uniformity cannot be obtained, resulting in ghosting after writing new images many times [15]. This can shorten the driving duration, improve the response speed, and reduce visibility of the ghost image effectively

Display Principle

Conclusions