基于热成像和根间隙修复算法的玉米根系表型检测

IF 0.7 4区 化学 Q4 SPECTROSCOPY 光谱学与光谱分析 Pub Date : 2020-01-01 DOI:10.3964/J.ISSN.1000-0593(2020)09-2845-06
Wei Lu, Zhao Han, X. Jian, Ji Zhou, Dong Jiang, Yanfeng Ding
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引用次数: 1

摘要

针对土壤遮挡导致根系图像信息不完整的问题,提出了一种利用热图像结合改进的Criminisi算法进行根系图像修复的方法,并研究了根系表型与种子活力之间的关系。首先,设计了一种适合玉米根系形态的环形双层石英培养装置,推动玉米根系沿内侧生长,在环形培养装置中分别种植3d和6d。基于土壤和水的显著热容差异,采用沿茎灌水后进行短时间热空气激励的方法,利用土壤和根部间隙水流之间的温差获取红外热图像。其次,选取预处理后的根热图像端点,采用改进的Criminisi算法进行匹配连接,修复根图像;最后,利用不同龄期玉米种子进行种子根系表型检测,验证了该方法的有效性。结果表明,所提出的热红外成像方法可以增强根系表型图像信息,与彩色图像相比,表型参数的精度提高了0.5 ~ 10%。根总长度(RTL)和根总数量(RTN)在衰老1 d后差异不显著,但在衰老3 d和6 d后差异显著,分别下降约20-35%和10-55%。总体而言,玉米根系表型参数RTN和RTL随老化天数呈显著负相关,可作为种子活力的重要指标参数。此外,RTN对种子活力的影响更为敏感。1d/3d和6d的根数增长分别比0 d的种子延迟了1天和2天。本文提出的基于热红外成像结合改进的Criminisi算法进行根系图像修复的根系表型检测方法可用于根系高通量无损检测,具有广阔的应用前景。
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Maize Root Phenotypic Detection Based on Thermal Imaging and Root Gap Repair Algorithm
Aiming at the problem of incomplete root image information because of blocking by the soil, the paper proposed a root phenotypic method by using thermal image combined with improved Criminisi algorithm for root image repair, and studied the relationship between the root phenotype and seed vigor. First, an annular double-layer quartz culture device adapted to maize root configuration was designed to push maize roots to grow along the inner 3d and 6d were planted in the annular culture device respectively. Base on the significant difference of heat capacity between soil and water, water was used to irrigate the seedings along their stems followed by short time hot air thermal excitation, and then infrared thermal images were captured based on the temperature difference between the soil and interstitial water flow around the roots. Secondly, the endpoints of the root thermal images after preprocessed were selected and matched for connecting using improved Criminisi algorithm to repair root image. Finally, different aged-day maize seeds were applied for seeding root phenotyping detection to verify the mentioned method which results shown that the proposed thermal infrared imaging method can help to enhance the root phenotypic image information which improve the precision of phenotypic parameters about 0.5-10% compared with color image. The was no significant difference of Root Total Length (RTL) and Root Total Number (RTN) after 1 d aging, but there were remarkable difference of RTL and RTN after 3 d and 6 d aging which decreased about 20-35% and 10-55% respectively. In general, the maize root phenotypic parameters such as RTN and RTL were significantly negative with the aging-day which can be used as important index parameters of seed vigor. Furthermore, RTN is more sensitive to impress a seed vigor. Root number of 1d/3d and 6d aging days increasing delayed about 1day and 2 day compared with 0 aging-day seeds respectively. The proposed root phenotypic detection method based on the thermal infrared imaging combined with improved Criminisi algorithm for root image repair can be used in root high throughput nondestructive detection which has a broad application prospect.
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来源期刊
光谱学与光谱分析
光谱学与光谱分析 Physics and Astronomy-Instrumentation
CiteScore
1.60
自引率
14.30%
发文量
18084
审稿时长
1.44444 months
期刊介绍:
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