TY - JOUR
T1 - Approaches for geospatial processing of field-based high-throughput plant phenomics data from ground vehicle platforms
AU - Wang, X.
AU - Thorp, K. R.
AU - White, J. W.
AU - French, A. N.
AU - Poland, J. A.
N1 - Generated from Scopus record by KAUST IRTS on 2022-09-13
PY - 2016/1/1
Y1 - 2016/1/1
N2 - Understanding the genetic basis of complex plant traits requires connecting genotype to phenotype information, known as the "G2P question." In the last three decades, genotyping methods have become highly developed. Much less innovation has occurred for measuring plant traits (phenotyping), particularly under field conditions. This imbalance has stimulated research to develop methods for field-based high-throughput plant phenotyping (HTPP). Sensors installed on ground vehicles can provide a huge amount of potentially transformative phenotypic measurements, orders of magnitude larger than provided by traditional phenotyping practice, but their utility requires accurate mapping. Using geospatial processing techniques, sensor data must be consistently matched to their corresponding field plots to establish links between breeding lines and measured phenotypes. This article examines problems and solutions for georeferencing sensor measurements from ground vehicle platforms for field-based HTPP. Using three case studies, the importance of vehicle heading for sensor positioning is examined. Three corresponding approaches for georeferencing are introduced based on different methods to estimate vehicle heading. For two of the cases, approaches to develop a field map of plot areas are addressed, where the issue is to ensure that sensor positions are correctly assigned to plots. Two solutions are proposed. One uses a geographic information system to design a field map before planting, while the other adopts an algorithm that calculates plot boundaries from the georeferenced sensor measurements. An advantage of the latter approach is the accommodation of irregular planting patterns. Using the algorithm to calculate the plot boundaries of a winter wheat field in Kansas, 98.4% of the calculated plot centers were within 0.4 m of the surveyed plot centers, and all of the calculated plot centers were within 0.6 m of the surveyed plot centers. While multiple options and software tools are available for geospatial processing of field-based HTPP data, they share common problems with sensor positioning and plot delineation. The options and tools presented in this study are distinguished by their practicality, accessibility, and ability to rapidly map phenotypic data.
AB - Understanding the genetic basis of complex plant traits requires connecting genotype to phenotype information, known as the "G2P question." In the last three decades, genotyping methods have become highly developed. Much less innovation has occurred for measuring plant traits (phenotyping), particularly under field conditions. This imbalance has stimulated research to develop methods for field-based high-throughput plant phenotyping (HTPP). Sensors installed on ground vehicles can provide a huge amount of potentially transformative phenotypic measurements, orders of magnitude larger than provided by traditional phenotyping practice, but their utility requires accurate mapping. Using geospatial processing techniques, sensor data must be consistently matched to their corresponding field plots to establish links between breeding lines and measured phenotypes. This article examines problems and solutions for georeferencing sensor measurements from ground vehicle platforms for field-based HTPP. Using three case studies, the importance of vehicle heading for sensor positioning is examined. Three corresponding approaches for georeferencing are introduced based on different methods to estimate vehicle heading. For two of the cases, approaches to develop a field map of plot areas are addressed, where the issue is to ensure that sensor positions are correctly assigned to plots. Two solutions are proposed. One uses a geographic information system to design a field map before planting, while the other adopts an algorithm that calculates plot boundaries from the georeferenced sensor measurements. An advantage of the latter approach is the accommodation of irregular planting patterns. Using the algorithm to calculate the plot boundaries of a winter wheat field in Kansas, 98.4% of the calculated plot centers were within 0.4 m of the surveyed plot centers, and all of the calculated plot centers were within 0.6 m of the surveyed plot centers. While multiple options and software tools are available for geospatial processing of field-based HTPP data, they share common problems with sensor positioning and plot delineation. The options and tools presented in this study are distinguished by their practicality, accessibility, and ability to rapidly map phenotypic data.
UR - http://elibrary.asabe.org/abstract.asp?aid=47474&t=3&dabs=Y&redir=&redirType=
UR - http://www.scopus.com/inward/record.url?scp=84998704958&partnerID=8YFLogxK
U2 - 10.13031/trans.59.11502
DO - 10.13031/trans.59.11502
M3 - Article
SN - 2151-0032
VL - 59
SP - 1053
EP - 1067
JO - Transactions of the ASABE
JF - Transactions of the ASABE
IS - 5
ER -