High Throughput Image Analytics Using Hough Transformation for Wheat Phenotyping

IF 0.8 4区农林科学 Q4 AGRICULTURAL ENGINEERING

Applied Engineering in Agriculture Pub Date : 2022-01-01 DOI:10.13031/aea.14956

James Y. Kim, Myung-Na Shin, Ji Hyun Lee, Weon-tai Jeon, Seung-Woo Cho

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引用次数: 1

Abstract

HighlightsRGB-based vegetation and leaf area indexes using a smartphone camera.Geo-rectification of skewed images via row detection using Hough Transformation.Open-source software to automate the image stitching and plot-level phenotypic metrics extraction. Abstract. An agricultural field is not always accessible for plant phenotyping with existing mobile platforms due to the limited space and regulated aviation area. Smartphone-triggered ground images were collected on a wheat field that has a limited access to monitor growth conditions of four wheat varieties: Shinyoung (SY), Joseong (JS), Taewoo (TW), and Cheongwoo (CW). For field mapping during the growing season, six sets of the raw images were acquired by a smartphone in an oblique view angle and processed to transform into nadir view images. Algorithms were developed to process the raw tile images for geometric rectification via row detection using Hough Transformation. Stitching software was developed to automate the high throughput image analytics of the skewed tile images into a stitched field image through deskewing, row alignment, overlap trimming, and resizing. Plot-level metrics were extracted to analyze plant growth of the wheat varieties using a gridding method for vegetation and leaf area indexes. The processed images resulted in the successful transformation and consistency of algorithms on image alignment and stitching. Plot-level analysis indicated that SY variety performed superior to the other varieties in both vegetation and leaf area indexes and was significantly different in the canopy coverage from the least performed TW variety. The image analytic methods developed in the study offer a flexible solution to stitch and align tile images by a hand-held camera in both oblique and nadir view via user-friendly interface software for high through plant phenotyping and can be adapted to other stationary or mobile imaging platforms in greenhouse and fields. Keywords: Calibration, Image processing, Phenotyping, Python, Software, Stitching.

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利用霍夫转化进行小麦表型分析的高通量图像分析

使用智能手机相机突出显示基于rgb的植被和叶面积指数。利用霍夫变换行检测对倾斜图像进行地理校正。开源软件，自动图像拼接和情节水平的表型指标提取。摘要由于有限的空间和受管制的航空区域，现有的移动平台并不总是可以进入农田进行植物表型分析。利用智能手机触发的地面图像，在有限通道的麦田采集了4个小麦品种的生长情况监测数据，这4个小麦品种分别是:信英(SY)、朝鲜(JS)、泰宇(TW)和清宇(CW)。为了在生长季节进行野外测绘，使用智能手机在斜视角下获取6组原始图像，处理后转换为谷底视图图像。提出了利用霍夫变换行检测对原始图像进行几何校正的算法。拼接软件的开发是为了通过倾斜、行对齐、重叠修剪和调整大小，自动将倾斜的瓦片图像的高通量图像分析转化为拼接的现场图像。采用植被和叶面积指数网格化方法，提取样地水平指标，分析小麦品种的植物生长情况。处理后的图像转换成功，图像对齐和拼接算法保持一致。样点水平分析表明，SY品种的植被和叶面积指数均优于其他品种，冠层盖度与表现最差的TW品种差异显著。本研究开发的图像分析方法提供了一种灵活的解决方案，通过用户友好的界面软件，在倾斜和最低点视图下，通过手持相机缝合和对齐瓦片图像，用于植物表型分析，并且可以适应温室和田地中的其他固定或移动成像平台。关键词:校准，图像处理，表型，Python，软件，拼接。

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来源期刊

Applied Engineering in Agriculture 农林科学-农业工程

CiteScore

1.80

自引率

11.10%

发文量

审稿时长

6 months

期刊介绍： This peer-reviewed journal publishes applications of engineering and technology research that address agricultural, food, and biological systems problems. Submissions must include results of practical experiences, tests, or trials presented in a manner and style that will allow easy adaptation by others; results of reviews or studies of installations or applications with substantially new or significant information not readily available in other refereed publications; or a description of successful methods of techniques of education, outreach, or technology transfer.