Impact of Camera Viewing Angle for Estimating Leaf Parameters of Wheat Plants from 3D Point Clouds

Impact of Camera Viewing Angle for Estimating Leaf Parameters of Wheat Plants from 3D Point Clouds

Estimation of plant canopy using low-altitude imagery can help monitor the normal growth status of crops and is highly beneficial for various digital farming applications such as precision crop protection. However, extracting 3D canopy information from raw images requires studying the effect of sens...

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Bibliographic Details
Main Authors: Minhui Li, Redmond R. Shamshiri, Michael Schirrmann, Cornelia Weltzien
Format: Article
Language:English
Published: MDPI AG 2021-06-01
Series:Agriculture
Subjects:
digital agriculture
3D photogrammetry
response surface methodology
structure from motion (SfM)
multi-view stereo (MVS)
Online Access:https://www.mdpi.com/2077-0472/11/6/563
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spelling doaj-697d61dcdf574a28baa5d34f94ba3d612021-07-01T00:40:13ZengMDPI AGAgriculture2077-04722021-06-011156356310.3390/agriculture11060563Impact of Camera Viewing Angle for Estimating Leaf Parameters of Wheat Plants from 3D Point CloudsMinhui Li0Redmond R. Shamshiri1Michael Schirrmann2Cornelia Weltzien3Agromechatronics, Technische Universität Berlin, Straße des 17, Juni 144, 10623 Berlin, GermanyAgromechatronics, Technische Universität Berlin, Straße des 17, Juni 144, 10623 Berlin, GermanyLeibniz Institute for Agricultural Engineering and Bioeconomy (ATB), Max-Eyth-Allee 100, 14469 Potsdam, GermanyAgromechatronics, Technische Universität Berlin, Straße des 17, Juni 144, 10623 Berlin, GermanyEstimation of plant canopy using low-altitude imagery can help monitor the normal growth status of crops and is highly beneficial for various digital farming applications such as precision crop protection. However, extracting 3D canopy information from raw images requires studying the effect of sensor viewing angle by taking into accounts the limitations of the mobile platform routes inside the field. The main objective of this research was to estimate wheat (<i>Triticum aestivum</i> L.) leaf parameters, including leaf length and width, from the 3D model representation of the plants. For this purpose, experiments with different camera viewing angles were conducted to find the optimum setup of a mono-camera system that would result in the best 3D point clouds. The angle-control analytical study was conducted on a four-row wheat plot with a row spacing of 0.17 m and with two seeding densities and growth stages as factors. Nadir and six oblique view image datasets were acquired from the plot with 88% overlapping and were then reconstructed to point clouds using Structure from Motion (SfM) and Multi-View Stereo (MVS) methods. Point clouds were first categorized into three classes as wheat canopy, soil background, and experimental plot. The wheat canopy class was then used to extract leaf parameters, which were then compared with those values from manual measurements. The comparison between results showed that (i) multiple-view dataset provided the best estimation for leaf length and leaf width, (ii) among the single-view dataset, canopy, and leaf parameters were best modeled with angles vertically at −45° and horizontally at 0° (VA −45, HA 0), while (iii) in nadir view, fewer underlying 3D points were obtained with a missing leaf rate of 70%. It was concluded that oblique imagery is a promising approach to effectively estimate wheat canopy 3D representation with SfM-MVS using a single camera platform for crop monitoring. This study contributes to the improvement of the proximal sensing platform for crop health assessment.https://www.mdpi.com/2077-0472/11/6/563digital agriculture3D photogrammetryresponse surface methodologystructure from motion (SfM)multi-view stereo (MVS)
collection DOAJ
language English
format Article
sources DOAJ
author Minhui Li
Redmond R. Shamshiri
Michael Schirrmann
Cornelia Weltzien
spellingShingle Minhui Li
Redmond R. Shamshiri
Michael Schirrmann
Cornelia Weltzien
Impact of Camera Viewing Angle for Estimating Leaf Parameters of Wheat Plants from 3D Point Clouds
Agriculture
digital agriculture
3D photogrammetry
response surface methodology
structure from motion (SfM)
multi-view stereo (MVS)
author_facet Minhui Li
Redmond R. Shamshiri
Michael Schirrmann
Cornelia Weltzien
author_sort Minhui Li
title Impact of Camera Viewing Angle for Estimating Leaf Parameters of Wheat Plants from 3D Point Clouds
title_short Impact of Camera Viewing Angle for Estimating Leaf Parameters of Wheat Plants from 3D Point Clouds
title_full Impact of Camera Viewing Angle for Estimating Leaf Parameters of Wheat Plants from 3D Point Clouds
title_fullStr Impact of Camera Viewing Angle for Estimating Leaf Parameters of Wheat Plants from 3D Point Clouds
title_full_unstemmed Impact of Camera Viewing Angle for Estimating Leaf Parameters of Wheat Plants from 3D Point Clouds
title_sort impact of camera viewing angle for estimating leaf parameters of wheat plants from 3d point clouds
publisher MDPI AG
series Agriculture
issn 2077-0472
publishDate 2021-06-01
description Estimation of plant canopy using low-altitude imagery can help monitor the normal growth status of crops and is highly beneficial for various digital farming applications such as precision crop protection. However, extracting 3D canopy information from raw images requires studying the effect of sensor viewing angle by taking into accounts the limitations of the mobile platform routes inside the field. The main objective of this research was to estimate wheat (<i>Triticum aestivum</i> L.) leaf parameters, including leaf length and width, from the 3D model representation of the plants. For this purpose, experiments with different camera viewing angles were conducted to find the optimum setup of a mono-camera system that would result in the best 3D point clouds. The angle-control analytical study was conducted on a four-row wheat plot with a row spacing of 0.17 m and with two seeding densities and growth stages as factors. Nadir and six oblique view image datasets were acquired from the plot with 88% overlapping and were then reconstructed to point clouds using Structure from Motion (SfM) and Multi-View Stereo (MVS) methods. Point clouds were first categorized into three classes as wheat canopy, soil background, and experimental plot. The wheat canopy class was then used to extract leaf parameters, which were then compared with those values from manual measurements. The comparison between results showed that (i) multiple-view dataset provided the best estimation for leaf length and leaf width, (ii) among the single-view dataset, canopy, and leaf parameters were best modeled with angles vertically at −45° and horizontally at 0° (VA −45, HA 0), while (iii) in nadir view, fewer underlying 3D points were obtained with a missing leaf rate of 70%. It was concluded that oblique imagery is a promising approach to effectively estimate wheat canopy 3D representation with SfM-MVS using a single camera platform for crop monitoring. This study contributes to the improvement of the proximal sensing platform for crop health assessment.
topic digital agriculture
3D photogrammetry
response surface methodology
structure from motion (SfM)
multi-view stereo (MVS)
url https://www.mdpi.com/2077-0472/11/6/563
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AT michaelschirrmann impactofcameraviewingangleforestimatingleafparametersofwheatplantsfrom3dpointclouds
AT corneliaweltzien impactofcameraviewingangleforestimatingleafparametersofwheatplantsfrom3dpointclouds
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