面向番茄植株相近色目标识别的多波段图像融合方法

doi:10.12133/j.smartag.2020.2.2.202002-SA001

Smart Agriculture ›› 2020, Vol. 2 ›› Issue (2): 126-134.doi: 10.12133/j.smartag.2020.2.2.202002-SA001

面向番茄植株相近色目标识别的多波段图像融合方法

冯青春^1,², 陈建², 成伟^3,⁴, 王秀^1,³()

^1.北京农业智能装备技术研究中心，北京 100097
^2.中国农业大学工学院，北京 100083
^3.国家农业智能装备工程技术研究中心，北京 100097
^4.农业智能装备技术北京市重点实验室，北京 100097

收稿日期:2020-02-06 修回日期:2020-04-18 出版日期:2020-06-30
基金资助:
国家自然科学基金项目(61703048);北京市农林科学院青年科研基金项目(QNJJ201722)
作者简介:冯青春（1987－），男，副研究员，研究方向为农业机器人。E-mail：fengqc@nercita.org.cn。
通信作者:

Multi-Band Image Fusion Method for Visually Identifying Tomato Plant’s Organs With Similar Color

FENG Qingchun^1,², CHEN Jian², CHENG Wei^3,⁴, WANG Xiu^1,³()

^1.Beijing Research Center of Intelligent Equipment for Agriculture, Beijing 100097, China
^2.College of Engineering, China Agricultural University, Beijing 100083, China
^3.National Research Center of Intelligent Equipment for Agriculture, Beijing 100097, China
^4.Beijing Key Laboratory of Intelligent Equipment Technology for Agriculture, Beijing 100097, China

Received:2020-02-06 Revised:2020-04-18 Online:2020-06-30

摘要/Abstract

摘要：

针对温室番茄智能化管理需要，研究茎秆、叶片和绿果等3类相近色目标的多波段图像融合方法，以凸显目标与背景亮度差异，提高目标视觉识别效率。根据其各自在300~1000 nm范围的反射光谱特征差异，建立了针对其光谱数据分类的Lasso正则化逻辑回归模型。基于模型的稀疏解特征，确定具有较大权值系数的450、600和900 nm等3个波段作为最优成像波段，在此基础上构建了温室番茄植株多波段图像在线采集系统。结合最优成像波段下相近色目标图像特征分析，提出了基于NSGA-II的多波段图像加权融合方法，以增强特定目标与近色背景物体的图像亮度差异。最后通过现场试验对多波段图像融合效果进行评估。结果表明，分别以茎秆、叶片和绿果器官作为识别目标，通过多波段图像融合处理后，目标与背景之间的图像灰度差异绝对差值相应达到单波段图像的2.02、8.63和7.89倍，即被识别目标与其他近色背景的亮度差异显著增强，且背景物的亮度波动得到抑制。本研究结果可以为农业环境近色目标视觉识别相关研究提供参考。

关键词: 农业机器人, 番茄植株, 相近色目标, 光谱特征, 图像融合, NSGA-II

Abstract:

Considering at the robotic management for tomato plants in the greenhouse, it is necessary to identify the stem, leaf and fruit with the similar color from the broad-band visible image. In order to highlight the difference between the target and background, and improve the identification efficiency, the multiple narrow-band image fusion method for identifying the tomato’s three similar-colored organs, including stem, leaf, and green fruit, was proposed, based on the spectral features of these organs. According to the 300-1000 nm spectral data of three organs, the regularized logistic regression model with Lasso for distinguishing their spectral characteristic was built. Based on the sparse solution of the model’s weight coefficients, the wavelengths 450, 600 and 900 nm with the maximum coefficients were determined as the optimal imaging band. The multi-spectral image capturing system was designed, which could output three images of optimal bands from the same view-field. The relationship between the organs’ image gray and their spectral feature was analyzed, and the optimal images could accurately show the organs’ reflection character at the various band. In order to obtain more significant distinctions, the weighted-fusion method based NSGA-II was proposed, which was supposed to combine the organ’s difference in the optimal band image. The algorithm’s objective function was defined to maximize the target-background difference and minimize the background-background difference. The coefficients obtained were adopted as the linear fusion factors for the optimal band images.Finally, the fusion method was evaluated based on intuitional and quantitative indexes, respectively considering the one among stem, leaf and green fruit as target, and the other two as the backgrounds. As the result showed, compared with the single optimal band image, the fused image greatly intensified the difference between the similar-colored target and background, and restrained the difference among the background. Specifically, the sum of absolute difference (SAD) was used to describe the grey value difference between the various organs, and the fusion result images’ SAD between the target and the background raised to 2.02, 8.63 and 7.89 times than the single band images. The Otsu automatic segmentation algorithm could respectively obtain the recognition accuracy of 71.14%, 60.32% and 98.32% for identifying the stem, leaf and fruit on the fusion result image. The research was supposed as a reference for the identification on similar-colored plant organs under agricultural condition.

Key words: agricultural robot, tomato plant, similar-colored organ, spectral feature, image fusion, NSGA-II

中图分类号:

TP751

冯青春, 陈建, 成伟, 王秀. 面向番茄植株相近色目标识别的多波段图像融合方法[J]. 智慧农业（中英文）, 2020, 2(2): 126-134.

FENG Qingchun, CHEN Jian, CHENG Wei, WANG Xiu. Multi-Band Image Fusion Method for Visually Identifying Tomato Plant’s Organs With Similar Color[J]. Smart Agriculture, 2020, 2(2): 126-134.

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面向番茄植株相近色目标识别的多波段图像融合方法

Multi-Band Image Fusion Method for Visually Identifying Tomato Plant’s Organs With Similar Color

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