全彩色LED显示屏亮色分离校正算法与应用
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摘要
为了解决全彩色LED显示屏逐点色度校正存在的色坐标采集困难,显示控制系统性能下降等问题,提出一种亮色分离校正算法。以分辨率8×8为最小单位,实现单个像素点非标准色域空间到标准色域空间转换矩阵的分离,色坐标的采集量降低至逐点色度校正的1/64,转换参量的个数降低至逐点色度校正的34.9%,扫描频率提升至逐点色度校正的2倍。亮色分离校正算法一定程度上解决了逐点色度校正的问题,同时提高了显示控制系统的性能。
Point-by-point chromaticity correction for full-color LED display screen is troubled by chromaticity coordinate value acquisition,display control system performance degradation,etc. As the minimum unit of resolution 8×8,separation of luminance and chromaticity correction algorithm is proposed to reduce acquisition of chromaticity to 1/64 and the number of conversion parameters is reduced to 34.9% by separation of conversion matrix from a non-standard gamut space to a standard gamut space,compared to point-by-point chromaticity correction algorithm,which result that the scan frequency increases two times by optimizing the conversion parameter precision. In conclusion,the separation of luminance and chromaticity correction algorithm solves the problem of point-by-point chromaticity correction algorithm to some extent,and improves the performance of the display control system.
Point-by-point chromaticity correction for full-color LED display screen is troubled by chromaticity coordinate value acquisition,display control system performance degradation,etc. As the minimum unit of resolution 8×8,separation of luminance and chromaticity correction algorithm is proposed to reduce acquisition of chromaticity to 1/64 and the number of conversion parameters is reduced to 34.9% by separation of conversion matrix from a non-standard gamut space to a standard gamut space,compared to point-by-point chromaticity correction algorithm,which result that the scan frequency increases two times by optimizing the conversion parameter precision. In conclusion,the separation of luminance and chromaticity correction algorithm solves the problem of point-by-point chromaticity correction algorithm to some extent,and improves the performance of the display control system.
引文
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[2] 陈育涛.基于FPGA实现光色度校正功能的LED全彩屏控制系统[D].华南理工大学,2016.
[3] 李熹霖.LED显示屏逐点色度亮度校正技术讲座[J].现代显示,2011(7):5-9.
[4] 陈宇,丁铁夫.显示量化误差对色域转化的影响[J].发光学报,2004,25(1):98-102.
[5] 朱承.基于FPGA的误差校正神经网络算法设计与实现[J].电子器件,2015,38(4):939-945.
[6] 郝亚茹,邓招奇,邓春健.LED显示控制系统移存频率加速方法研究[J].液晶与显示,2016,31(5):470-476.
[7] 郝亚茹,邓招奇,邓春健.基于亮度修正模型的多参量权衡与灰度权值算法研究[J].发光学报,2016,37(4):503-511.
[8] 宋超,王瑞光,陈宇.LED显示屏色域边界的快速计算[J].发光学报,2013,34(7):924-929.
[9] 刘瑞兰,林若愚.基于FPGA的线阵CCD光强自动采集系统设计[J].传感技术学报,2017,30(1):152-156.
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