Canopy Roughness: A New Phenotypic Trait to Estimate Aboveground Biomass from Unmanned Aerial System

Overview

Journal Plant Phenomics

Date 2021 Feb 12

PMID 33575668

Citations 8

Authors

Monica Herrero-Huerta

Alexander Bucksch

Eetu Puttonen

Katy M Rainey

Affiliations

Soon will be listed here.

Abstract

Cost-effective phenotyping methods are urgently needed to advance crop genetics in order to meet the food, fuel, and fiber demands of the coming decades. Concretely, characterizing plot level traits in fields is of particular interest. Recent developments in high-resolution imaging sensors for UAS (unmanned aerial systems) focused on collecting detailed phenotypic measurements are a potential solution. We introduce canopy roughness as a new plant plot-level trait. We tested its usability with soybean by optical data collected from UAS to estimate biomass. We validate canopy roughness on a panel of 108 soybean [Glycine max (L.) Merr.] recombinant inbred lines in a multienvironment trial during the R2 growth stage. A senseFly eBee UAS platform obtained aerial images with a senseFly S.O.D.A. compact digital camera. Using a structure from motion (SfM) technique, we reconstructed 3D point clouds of the soybean experiment. A novel pipeline for feature extraction was developed to compute canopy roughness from point clouds. We used regression analysis to correlate canopy roughness with field-measured aboveground biomass (AGB) with a leave-one-out cross-validation. Overall, our models achieved a coefficient of determination ( ) greater than 0.5 in all trials. Moreover, we found that canopy roughness has the ability to discern AGB variations among different genotypes. Our test trials demonstrate the potential of canopy roughness as a reliable trait for high-throughput phenotyping to estimate AGB. As such, canopy roughness provides practical information to breeders in order to select phenotypes on the basis of UAS data.

Citing Articles

Accurate LAI estimation of soybean plants in the field using deep learning and clustering algorithms.

Shi B, Guo L, Yu L Front Plant Sci. 2025; 15:1501612.

PMID: 39911650 PMC: 11794303. DOI: 10.3389/fpls.2024.1501612.

Mapping rapeseed () aboveground biomass in different periods using optical and phenotypic metrics derived from UAV hyperspectral and RGB imagery.

Sun C, Zhang W, Zhao G, Wu Q, Liang W, Ren N Front Plant Sci. 2024; 15:1504119.

PMID: 39711583 PMC: 11659009. DOI: 10.3389/fpls.2024.1504119.

Multi temporal multispectral UAV remote sensing allows for yield assessment across European wheat varieties already before flowering.

Camenzind M, Yu K Front Plant Sci. 2024; 14:1214931.

PMID: 38235203 PMC: 10791776. DOI: 10.3389/fpls.2023.1214931.

Drone-Based Harvest Data Prediction Can Reduce On-Farm Food Loss and Improve Farmer Income.

Wang H, Li T, Nishida E, Kato Y, Fukano Y, Guo W Plant Phenomics. 2023; 5:0086.

PMID: 37692103 PMC: 10484300. DOI: 10.34133/plantphenomics.0086.

How to make sense of 3D representations for plant phenotyping: a compendium of processing and analysis techniques.

Harandi N, Vandenberghe B, Vankerschaver J, Depuydt S, Van Messem A Plant Methods. 2023; 19(1):60.

PMID: 37353846 PMC: 10288709. DOI: 10.1186/s13007-023-01031-z.

References

Araus J, Cairns J . Field high-throughput phenotyping: the new crop breeding frontier. Trends Plant Sci. 2013; 19(1):52-61. DOI: 10.1016/j.tplants.2013.09.008. View

Anderson 2nd S, Murray S, Chen Y, Malambo L, Chang A, Popescu S . Unoccupied aerial system enabled functional modeling of maize height reveals dynamic expression of loci. Plant Direct. 2020; 4(5):e00223. PMC: 7212003. DOI: 10.1002/pld3.223. View

Dobbels A, Lorenz A . Soybean iron deficiency chlorosis high throughput phenotyping using an unmanned aircraft system. Plant Methods. 2019; 15:97. PMC: 6700811. DOI: 10.1186/s13007-019-0478-9. View

Lopez M, Xavier A, Rainey K . Phenotypic Variation and Genetic Architecture for Photosynthesis and Water Use Efficiency in Soybean ( L. Merr). Front Plant Sci. 2019; 10:680. PMC: 6543851. DOI: 10.3389/fpls.2019.00680. View

Moreira F, Hearst A, Cherkauer K, Rainey K . Improving the efficiency of soybean breeding with high-throughput canopy phenotyping. Plant Methods. 2019; 15:139. PMC: 6862841. DOI: 10.1186/s13007-019-0519-4. View

Xavier A, Hall B, Hearst A, Cherkauer K, Rainey K . Genetic Architecture of Phenomic-Enabled Canopy Coverage in . Genetics. 2017; 206(2):1081-1089. PMC: 5499164. DOI: 10.1534/genetics.116.198713. View

Guo W, Zheng B, Potgieter A, Diot J, Watanabe K, Noshita K . Aerial Imagery Analysis - Quantifying Appearance and Number of Sorghum Heads for Applications in Breeding and Agronomy. Front Plant Sci. 2018; 9:1544. PMC: 6206408. DOI: 10.3389/fpls.2018.01544. View

Puttonen E, Lehtomaki M, Litkey P, Nasi R, Feng Z, Liang X . A Clustering Framework for Monitoring Circadian Rhythm in Structural Dynamics in Plants From Terrestrial Laser Scanning Time Series. Front Plant Sci. 2019; 10:486. PMC: 6499199. DOI: 10.3389/fpls.2019.00486. View

Tattaris M, Reynolds M, Chapman S . A Direct Comparison of Remote Sensing Approaches for High-Throughput Phenotyping in Plant Breeding. Front Plant Sci. 2016; 7:1131. PMC: 4971441. DOI: 10.3389/fpls.2016.01131. View

10.

Duan T, Zheng B, Guo W, Ninomiya S, Guo Y, Chapman S . Comparison of ground cover estimates from experiment plots in cotton, sorghum and sugarcane based on images and ortho-mosaics captured by UAV. Funct Plant Biol. 2020; 44(1):169-183. DOI: 10.1071/FP16123. View

11.

Maes W, Steppe K . Perspectives for Remote Sensing with Unmanned Aerial Vehicles in Precision Agriculture. Trends Plant Sci. 2018; 24(2):152-164. DOI: 10.1016/j.tplants.2018.11.007. View

12.

Herrero-Huerta M, Lindenbergh R, Gard W . Leaf Movements of Indoor Plants Monitored by Terrestrial LiDAR. Front Plant Sci. 2018; 9:189. PMC: 5829619. DOI: 10.3389/fpls.2018.00189. View

13.

Tresch L, Mu Y, Itoh A, Kaga A, Taguchi K, Hirafuji M . Easy MPE: Extraction of Quality Microplot Images for UAV-Based High-Throughput Field Phenotyping. Plant Phenomics. 2020; 2019:2591849. PMC: 7706339. DOI: 10.34133/2019/2591849. View

14.

Browne . Cross-Validation Methods. J Math Psychol. 2000; 44(1):108-132. DOI: 10.1006/jmps.1999.1279. View

15.

Mochida K, Koda S, Inoue K, Hirayama T, Tanaka S, Nishii R . Computer vision-based phenotyping for improvement of plant productivity: a machine learning perspective. Gigascience. 2018; 8(1). PMC: 6312910. DOI: 10.1093/gigascience/giy153. View

16.

Tirado S, Hirsch C, Springer N . UAV-based imaging platform for monitoring maize growth throughout development. Plant Direct. 2020; 4(6):e00230. PMC: 7278367. DOI: 10.1002/pld3.230. View

17.

Jiang Y, Li C, Takeda F, Kramer E, Ashrafi H, Hunter J . 3D point cloud data to quantitatively characterize size and shape of shrub crops. Hortic Res. 2019; 6:43. PMC: 6441659. DOI: 10.1038/s41438-019-0123-9. View

18.

Herrero-Huerta M, Rodriguez-Gonzalvez P, Rainey K . Yield prediction by machine learning from UAS-based mulit-sensor data fusion in soybean. Plant Methods. 2020; 16:78. PMC: 7268475. DOI: 10.1186/s13007-020-00620-6. View

19.

Rueda-Ayala V, Pena J, Hoglind M, Bengochea-Guevara J, Andujar D . Comparing UAV-Based Technologies and RGB-D Reconstruction Methods for Plant Height and Biomass Monitoring on Grass Ley. Sensors (Basel). 2019; 19(3). PMC: 6387457. DOI: 10.3390/s19030535. View

20.

Li J, Shi Y, Veeranampalayam-Sivakumar A, Schachtman D . Elucidating Sorghum Biomass, Nitrogen and Chlorophyll Contents With Spectral and Morphological Traits Derived From Unmanned Aircraft System. Front Plant Sci. 2018; 9:1406. PMC: 6176777. DOI: 10.3389/fpls.2018.01406. View