Remote, aerial phenotyping of maize traits with a mobile multi-sensor approach

BackgroundField-based high throughput phenotyping is a bottleneck for crop breeding research. We present a novel method for repeated remote phenotyping of maize genotypes using the Zeppelin NT aircraft as an experimental sensor platform. The system has the advantage of a low altitude and cruising speed compared to many drones or airplanes, thus enhancing image resolution while reducing blurring effects. Additionally there was no restriction in sensor weight. Using the platform, red, green and blue colour space (RGB), normalized difference vegetation index (NDVI) and thermal images were acquired throughout the growing season and compared with traits measured on the ground. Ground control points were used to co-register the images and to overlay them with a plot map.ResultsNDVI images were better suited than RGB images to segment plants from soil background leading to two separate traits: the canopy cover (CC) and its NDVI value (NDVIPlant). Remotely sensed CC correlated well with plant density, early vigour, leaf size, and radiation interception. NDVIPlant was less well related to ground truth data. However, it related well to the vigour rating, leaf area index (LAI) and leaf biomass around flowering and to very late senescence rating. Unexpectedly, NDVIPlant correlated negatively with chlorophyll meter measurements. This could be explained, at least partially, by methodical differences between the used devices and effects imposed by the population structure. Thermal images revealed information about the combination of radiation interception, early vigour, biomass, plant height and LAI. Based on repeatability values, we consider two row plots as best choice to balance between precision and available field space. However, for thermography, more than two rows improve the precision.ConclusionsWe made important steps towards automated processing of remotely sensed data, and demonstrated the value of several procedural steps, facilitating the application in plant genetics and breeding. Important developments are: the ability to monitor throughout the season, robust image segmentation and the identification of individual plots in images from different sensor types at different dates. Remaining bottlenecks are: sufficient ground resolution, particularly for thermal imaging, as well as a deeper understanding of the relatedness of remotely sensed data and basic crop characteristics.

[1]  Michael Elad,et al.  Fast and robust multiframe super resolution , 2004, IEEE Transactions on Image Processing.

[2]  S. Dong,et al.  QTL mapping of maize (Zea mays) stay-green traits and their relationship to yield. , 2009 .

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

[4]  D. Inzé,et al.  Translational research: from pot to plot. , 2014, Plant biotechnology journal.

[5]  J. Araus,et al.  Field high-throughput phenotyping: the new crop breeding frontier. , 2014, Trends in plant science.

[6]  Mateo Vargas,et al.  Dissecting maize productivity: ideotypes associated with grain yield under drought stress and well-watered conditions. , 2012, Journal of integrative plant biology.

[7]  Eduardo Alberto Tambussi,et al.  Analysis of early vigour in twenty modern cultivars of bread wheat (Triticum aestivum L.) , 2012, Crop and Pasture Science.

[8]  A. Walter,et al.  REVIEW: PART OF A HIGHLIGHT ON BREEDING STRATEGIES FOR FORAGE AND GRASS IMPROVEMENT Advanced phenotyping offers opportunities for improved breeding of forage and turf species , 2012 .

[9]  J. Araus,et al.  Infrared Thermal Imaging as a Rapid Tool for Identifying Water-Stress Tolerant Maize Genotypes of Different Phenology , 2013 .

[10]  B. Mistele,et al.  Identification of stay-green and early senescence phenotypes in high-yielding winter wheat, and their relationship to grain yield and grain protein concentration using high-throughput phenotyping techniques. , 2014, Functional plant biology : FPB.

[11]  Albrecht E. Melchinger,et al.  High-throughput non-destructive biomass determination during early plant development in maize under field conditions , 2011 .

[12]  D. Raes,et al.  The effect of tillage, crop rotation and residue management on maize and wheat growth and development evaluated with an optical sensor , 2011 .

[13]  K. Soudani,et al.  Ground-based Network of NDVI measurements for tracking temporal dynamics of canopy structure and vegetation phenology in different biomes , 2012 .

[14]  Jose A. Jiménez-Berni,et al.  Proximal Remote Sensing Buggies and Potential Applications for Field-Based Phenotyping , 2014 .

[15]  M. M. Chaves,et al.  Thermography to explore plant-environment interactions. , 2013, Journal of experimental botany.

[16]  Vincent G. Ambrosia,et al.  Unmanned Aircraft Systems in Remote Sensing and Scientific Research: Classification and Considerations of Use , 2012, Remote. Sens..

[17]  H. Jones,et al.  Thermal infrared imaging of crop canopies for the remote diagnosis and quantification of plant responses to water stress in the field. , 2009, Functional plant biology : FPB.

[18]  M. Tester,et al.  Phenomics--technologies to relieve the phenotyping bottleneck. , 2011, Trends in plant science.

[19]  M. Meron,et al.  Evaluation of different approaches for estimating and mapping crop water status in cotton with thermal imaging , 2010, Precision Agriculture.

[20]  P. Debaeke,et al.  Effect of Soil Phosphorus on Leaf Development and Senescence Dynamics of Field‐Grown Maize , 2000 .

[21]  H. Thomas Senescence, ageing and death of the whole plant. , 2013, The New phytologist.

[22]  J. Deckers,et al.  Reference Base for Soil Resources , 2002 .

[23]  Wolfram Spreer,et al.  Use of thermography for high throughput phenotyping of tropical maize adaptation in water stress , 2011 .

[24]  H. Brown,et al.  Radiation capture and radiation use efficiency in response to N supply for crop species with contrasting canopies , 2013 .

[25]  Stanislaus J. Schymanski,et al.  Stomatal Control and Leaf Thermal and Hydraulic Capacitances under Rapid Environmental Fluctuations , 2013, PloS one.

[26]  Craig S. T. Daughtry,et al.  A visible band index for remote sensing leaf chlorophyll content at the canopy scale , 2013, Int. J. Appl. Earth Obs. Geoinformation.

[27]  Wilhelm Burger,et al.  Digital Image Processing - An Algorithmic Introduction using Java , 2008, Texts in Computer Science.

[28]  J. Deckers,et al.  World Reference Base for Soil Resources , 1998 .

[29]  Tadao Ando,et al.  Plant Nutrition for Sustainable Food Production and Environment , 2016, Developments in Plant and Soil Sciences.

[30]  Gustavo A. Slafer,et al.  Consequences of breeding on biomass, radiation interception and radiation-use efficiency in wheat , 1997 .

[31]  H. Jones,et al.  Remote Sensing of Vegetation: Principles, Techniques, and Applications , 2010 .

[32]  R. H. Fox,et al.  Comparison of Late‐Season Diagnostic Tests for Predicting Nitrogen Status of Corn , 2001 .

[33]  Frank Liebisch,et al.  Characterization of crop vitality and resource use efficiency by means of combining imaging spectroscopy based plant traits , 2014, 2014 6th Workshop on Hyperspectral Image and Signal Processing: Evolution in Remote Sensing (WHISPERS).

[34]  Andrew E. Suyker,et al.  An alternative method using digital cameras for continuous monitoring of crop status , 2012 .

[35]  Jeffrey W. White,et al.  Field-based phenomics for plant genetics research , 2012 .

[36]  Chunhua Zhang,et al.  The application of small unmanned aerial systems for precision agriculture: a review , 2012, Precision Agriculture.

[37]  José Crossa,et al.  Identification of Drought, Heat, and Combined Drought and Heat Tolerant Donors in Maize , 2013 .

[38]  Abraham J. Escobar-Gutiérrez,et al.  Senescence in field-grown maize: From flowering to harvest , 2012 .

[39]  M. Tester,et al.  Quantifying the three main components of salinity tolerance in cereals. , 2009, Plant, cell & environment.

[40]  J. Araus,et al.  Enhancing drought tolerance in C(4) crops. , 2011, Journal of experimental botany.

[41]  Pierre Hiernaux,et al.  Non-destructive measurement of plant growth and nitrogen status of pearl millet with low-altitude aerial photography , 1997 .

[42]  J. I. Lizaso,et al.  A leaf area model to simulate cultivar-specific expansion and senescence of maize leaves , 2003 .