Simulating an Autonomously Operating Low-Cost Static Terrestrial LiDAR for Multitemporal Maize Crop Height Measurements

In order to optimize agricultural processes, near real-time spatial information about in-field variations, such as crop height development (i.e., changes over time), is indispensable. This development can be captured with a LiDAR system. However, its applicability in precision agriculture is often hindered due to high costs and unstandardized processing methods. This study investigates the potential of an autonomously operating low-cost static terrestrial laser scanner (TLS) for multitemporal height monitoring of maize crops. A low-cost system is simulated by artificially reducing the point density of data captured during eight different campaigns. The data were used to derive and assess crop height models (CHM). Results show that heights calculated with CHM based on the unreduced point cloud are accurate when compared to manually measured heights (mean deviation = 0.02 m, standard deviation = 0.15 m, root mean square error (RMSE) = 0.16 m). When reducing the point cloud to 2% of its original size to simulate a low-cost system, this difference increases (mean deviation = 0.12 m, standard deviation = 0.19 m, RMSE = 0.22 m). We found that applying the simulated low-cost TLS system in precision agriculture is possible with acceptable accuracy up to an angular scan resolution of 8 mrad (i.e., point spacing of 80 mm at 10 m distance). General guidelines for the measurement set-up and an automatically executable method for CHM generation and assessment are provided and deserve consideration in further studies.

[1]  Hans Jørgen Andersen,et al.  Geometric plant properties by relaxed stereo vision using simulated annealing , 2005 .

[2]  Y. Miao,et al.  Transferability of Models for Estimating Paddy Rice Biomass from Spatial Plant Height Data , 2015 .

[3]  Qiang Cao,et al.  Multitemporal crop surface models: accurate plant height measurement and biomass estimation with terrestrial laser scanning in paddy rice , 2014 .

[4]  F. Bongers Methods to assess tropical rain forest canopy structure: an overview , 2001, Plant Ecology.

[5]  Juliane Bendig,et al.  UAV-based Imaging for Multi-Temporal, very high Resolution Crop Surface Models to monitor Crop Growth Variability , 2013 .

[6]  Kenji Omasa,et al.  3-D Modeling of Tomato Canopies Using a High-Resolution Portable Scanning Lidar for Extracting Structural Information , 2011, Sensors.

[7]  Paul J. Besl,et al.  Method for registration of 3-D shapes , 1992, Other Conferences.

[8]  Steven R. Raine,et al.  Applied machine vision of plants – a review with implications for field deployment in automated farming operations 1 , 2010 .

[9]  A. Eltner,et al.  Accuracy constraints of terrestrial Lidar data for soil erosion measurement: Application to a Mediterranean field plot , 2015 .

[10]  Bernhard Höfle,et al.  Fusion of multi‐resolution surface (terrestrial laser scanning) and subsurface geodata (ERT, SRT) for karst landform investigation and geomorphometric quantification , 2013 .

[11]  A. Escolà,et al.  Ultrasonic and LIDAR Sensors for Electronic Canopy Characterization in Vineyards: Advances to Improve Pesticide Application Methods , 2011, Sensors.

[12]  W. Stuppy,et al.  Three-dimensional analysis of plant structure using high-resolution X-ray computed tomography. , 2003, Trends in plant science.

[13]  Qin Zhang,et al.  Development of a stereovision sensing system for 3D crop row structure mapping and tractor guidance , 2008 .

[14]  D. Ehlert,et al.  Suitability of a laser rangefinder to characterize winter wheat , 2010, Precision Agriculture.

[15]  J. Léon,et al.  High-precision laser scanning system for capturing 3D plant architecture and analysing growth of cereal plants , 2014 .

[16]  J. Edwards Maize growth and development. , 2009 .

[17]  R. Sanz,et al.  A review of methods and applications of the geometric characterization of tree crops in agricultural activities , 2012 .

[18]  J. C. McGrew,et al.  An Introduction to Statistical Problem Solving in Geography , 1993 .

[19]  J. Phattaralerphong,et al.  A method for 3D reconstruction of tree crown volume from photographs: assessment with 3D-digitized plants. , 2005, Tree physiology.

[20]  Paul J. Besl,et al.  A Method for Registration of 3-D Shapes , 1992, IEEE Trans. Pattern Anal. Mach. Intell..

[21]  D. Mulla Twenty five years of remote sensing in precision agriculture: Key advances and remaining knowledge gaps , 2013 .

[22]  C. Glasbey,et al.  SPICY: towards automated phenotyping of large pepper plants in the greenhouse. , 2012, Functional plant biology : FPB.

[23]  Sebastian Riedel,et al.  Automated Analysis of Barley Organs Using 3D Laser Scanning: An Approach for High Throughput Phenotyping , 2014, Sensors.

[24]  G. Bareth,et al.  Terrestrial laser scanning for plant height measurement and biomass estimation of maize , 2014 .

[25]  Alexandre Escolà,et al.  Discriminating Crop, Weeds and Soil Surface with a Terrestrial LIDAR Sensor , 2013, Sensors.

[26]  Harri Kaartinen,et al.  Remote Sensing Radiometric Calibration of Terrestrial Laser Scanners with External Reference Targets , 2022 .

[27]  Norbert Pfeifer,et al.  OPALS - A framework for Airborne Laser Scanning data analysis , 2014, Comput. Environ. Urban Syst..

[28]  Simon Bennertz,et al.  Estimating Biomass of Barley Using Crop Surface Models (CSMs) Derived from UAV-Based RGB Imaging , 2014, Remote. Sens..

[29]  Alexandre Escolà,et al.  Innovative LIDAR 3D Dynamic Measurement System to Estimate Fruit-Tree Leaf Area , 2011, Sensors.

[30]  N. Zhang,et al.  Precision agriculture—a worldwide overview , 2002 .

[31]  Neil Sims,et al.  Automated In-Situ Laser Scanner for Monitoring Forest Leaf Area Index , 2014, Sensors.

[32]  A. Escolà,et al.  An Electronic Control System for Pesticide Application Proportional to the Canopy Width of Tree Crops , 2006 .

[33]  Bernhard Höfle,et al.  Radiometric Correction of Terrestrial LiDAR Point Cloud Data for Individual Maize Plant Detection , 2014, IEEE Geoscience and Remote Sensing Letters.

[34]  K. Omasa,et al.  3D lidar imaging for detecting and understanding plant responses and canopy structure. , 2006, Journal of experimental botany.

[35]  Qin Zhang,et al.  Creation of Three-dimensional Crop Maps based on Aerial Stereoimages , 2005 .

[36]  K. Moffett,et al.  Remote Sens , 2015 .

[37]  Pete Watt,et al.  Measuring forest structure with terrestrial laser scanning , 2005 .

[38]  Nora Tilly,et al.  Fusion of Plant Height and Vegetation Indices for the Estimation of Barley Biomass , 2015, Remote. Sens..

[39]  Qamar-uz- Zaman,et al.  Performance of an Ultrasonic Tree Volume Measurement System in Commercial Citrus Groves , 2005, Precision Agriculture.

[40]  Q. Zaman,et al.  EFFECTS OF FOLIAGE DENSITY AND GROUND SPEED ON ULTRASONIC MEASUREMENT OF CITRUS TREE VOLUME , 2004 .

[41]  Derek D. Lichti,et al.  Static Calibration and Analysis of the Velodyne HDL-64E S2 for High Accuracy Mobile Scanning , 2010, Remote. Sens..

[42]  I. Jonckheere,et al.  Influence of measurement set-up of ground-based LiDAR for derivation of tree structure , 2006 .

[43]  K. Keightley,et al.  Original paper: 3D volumetric modeling of grapevine biomass using Tripod LiDAR , 2010 .

[44]  Bernhard Höfle,et al.  Effects of Reduced Terrestrial LiDAR Point Density on High-Resolution Grain Crop Surface Models in Precision Agriculture , 2014, Sensors.

[45]  Dirk Hoffmeister,et al.  High-resolution Crop Surface Models (CSM) and Crop Volume Models (CVM) on field level by terrestrial laser scanning , 2009, International Symposium on Digital Earth.

[46]  Bernhard Höfle,et al.  Comparative classification analysis of post-harvest growth detection from terrestrial LiDAR point clouds in precision agriculture , 2015 .

[47]  A. Escolà,et al.  Obtaining the three-dimensional structure of tree orchards from remote 2D terrestrial LIDAR scanning , 2009 .

[48]  V. Alchanatis,et al.  Review: Sensing technologies for precision specialty crop production , 2010 .

[49]  J. Eitel,et al.  A lightweight, low cost autonomously operating terrestrial laser scanner for quantifying and monitoring ecosystem structural dynamics , 2013 .

[50]  Lei Zhang,et al.  A LIDAR-based crop height measurement system for Miscanthus giganteus , 2012 .

[51]  Cristiano Fragassa,et al.  Ground monitoring the light–shadow windows of a tree canopy to yield canopy light interception and morphological traits , 2000 .

[52]  Anttoni Jaakkola,et al.  Analysis of Incidence Angle and Distance Effects on Terrestrial Laser Scanner Intensity: Search for Correction Methods , 2011, Remote. Sens..

[53]  H. Zub,et al.  Key traits for biomass production identified in different Miscanthus species at two harvest dates. , 2011 .

[54]  Matthias Rothmund,et al.  Precision agriculture on grassland : Applications, perspectives and constraints , 2008 .

[55]  Sylvain G. Leblanc,et al.  Methodology comparison for canopy structure parameters extraction from digital hemispherical photography in boreal forests , 2005 .