Leaf to canopy upscaling approach affects the estimation of canopy traits

In remote sensing applications, leaf traits are often upscaled to canopy level using sunlit leaf samples collected from the upper canopy. The implicit assumption is that the top of canopy foliage material dominates canopy reflectance and the variability in leaf traits across the canopy is very small. However, the effect of different approaches of upscaling leaf traits to canopy level on model performance and estimation accuracy remains poorly understood. This is especially important in short or sparse canopies where foliage material from the lower canopy potentially contributes to the canopy reflectance. The principal aim of this study is to examine the effect of different approaches when upscaling leaf traits to canopy level on model performance and estimation accuracy using spectral measurements (in-situ canopy hyperspectral and simulated Sentinel-2 data) in short woody vegetation. To achieve this, we measured foliar nitrogen (N), leaf mass per area (LMA), foliar chlorophyll and carbon together with leaf area index (LAI) at three vertical canopy layers (lower, middle and upper) along the plant stem in a controlled laboratory environment. We then upscaled the leaf traits to canopy level by multiplying leaf traits by LAI based on different combinations of the three canopy layers. Concurrently, in-situ canopy reflectance was measured using an ASD FieldSpec-3 Pro FR spectrometer, and the canopy traits were related to in-situ spectral measurements using partial least square regression (PLSR). The PLSR models were cross-validated based on repeated k-fold, and the normalized root mean square errors (nRMSEcv) obtained from each upscaling approach were compared using one-way analysis of variance (ANOVA) followed by Tukey’s post hoc test. Results of the study showed that leaf-to-canopy upscaling approaches that consider the contribution of leaf traits from the exposed upper canopy layer together with the shaded middle canopy layer yield significantly (p < 0.05) lower error (nRMSEcv < 0.2 for canopy N, LMA and carbon) as well as high explained variance (R2 > 0.71) for both in-situ hyperspectral and simulated Sentinel-2 data. The widely-used upscaling approach that considers only leaf traits from the upper illuminated canopy layer yielded a relatively high error (nRMSEcv>0.2) and lower explained variance (R2 < 0.71) for canopy N, LMA and carbon. In contrast, canopy chlorophyll upscaled based on leaf samples collected from the upper canopy and total canopy LAI exhibited a more accurate relationship with spectral measurements compared with other upscaling approaches. Results of this study demonstrate that leaf to canopy upscaling approaches have a profound effect on canopy traits estimation for both in-situ hyperspectral measurements and simulated Sentinel-2 data in short woody vegetation. These findings have implications for field sampling protocols of leaf traits measurement as well as upscaling leaf traits to canopy level especially in short and less foliated vegetation where leaves from the lower canopy contribute to the canopy reflectance.

[1]  Pingheng Li,et al.  Developing and validating novel hyperspectral indices for leaf area index estimation: Effect of canopy vertical heterogeneity , 2013 .

[2]  P. Thenkabail,et al.  Hyperspectral Vegetation Indices and Their Relationships with Agricultural Crop Characteristics , 2000 .

[3]  Max Kuhn,et al.  Building Predictive Models in R Using the caret Package , 2008 .

[4]  A. Skidmore,et al.  Reflectance Spectroscopy of Biochemical Components as Indicators of Tea , 2010 .

[5]  B. Yoder,et al.  Predicting nitrogen and chlorophyll content and concentrations from reflectance spectra (400–2500 nm) at leaf and canopy scales , 1995 .

[6]  Jan G. P. W. Clevers,et al.  Remote estimation of crop and grass chlorophyll and nitrogen content using red-edge bands on Sentinel-2 and -3 , 2013, Int. J. Appl. Earth Obs. Geoinformation.

[7]  C. A. Mücher,et al.  Environmental science: Agree on biodiversity metrics to track from space , 2015, Nature.

[8]  B. Kowalski,et al.  Partial least-squares regression: a tutorial , 1986 .

[9]  Holly Croft,et al.  Evaluating leaf chlorophyll content prediction from multispectral remote sensing data within a physically-based modelling framework , 2015 .

[10]  Chunjiang Zhao,et al.  Non-uniform vertical nitrogen distribution within plant canopy and its estimation by remote sensing: A review , 2013 .

[11]  S. Wold,et al.  PLS-regression: a basic tool of chemometrics , 2001 .

[12]  P. Treitz,et al.  Canopy chlorophyll concentration estimation using hyperspectral and lidar data for a boreal mixedwood forest in northern Ontario, Canada , 2008 .

[13]  Jing M. Chen,et al.  Daily canopy photosynthesis model through temporal and spatial scaling for remote sensing applications , 1999 .

[14]  Simon J. Hook,et al.  Linking seasonal foliar traits to VSWIR-TIR spectroscopy across California ecosystems , 2016 .

[15]  Jan G. P. W. Clevers,et al.  Optical remote sensing and the retrieval of terrestrial vegetation bio-geophysical properties - A review , 2015 .

[16]  Ronghua Ma,et al.  Estimating the Total Nitrogen Concentration of Reed Canopy with Hyperspectral Measurements Considering a Non-Uniform Vertical Nitrogen Distribution , 2016, Remote. Sens..

[17]  Anming Bao,et al.  Leaf and canopy water content estimation in cotton using hyperspectral indices and radiative transfer models , 2014, Int. J. Appl. Earth Obs. Geoinformation.

[18]  Simon Scheiter,et al.  Next-generation dynamic global vegetation models: learning from community ecology. , 2013, The New phytologist.

[19]  M. Schaepman,et al.  Retrieval of spruce leaf chlorophyll content from airborne image data using continuum removal and radiative transfer , 2013 .

[20]  Andrew K. Skidmore,et al.  Using discrete‐return airborne laser scanning to quantify number of canopy strata across diverse forest types , 2016 .

[21]  Lalit Kumar,et al.  Imaging Spectrometry and Vegetation Science , 2001 .

[22]  I. Wakeling,et al.  A test of significance for partial least squares regression , 1993 .

[23]  David J. Gibson,et al.  Grasses and Grassland Ecology , 2009 .

[24]  Anatoly A. Gitelson,et al.  Assessment of Canopy Chlorophyll Content Retrieval in Maize and Soybean: Implications of Hysteresis on the Development of Generic Algorithms , 2017, Remote. Sens..

[25]  Yuhong He,et al.  Scaling up Semi-Arid Grassland Biochemical Content from the Leaf to the Canopy Level: Challenges and Opportunities , 2010, Sensors.

[26]  Zhihao Qin,et al.  Estimation of Crop LAI using hyperspectral vegetation indices and a hybrid inversion method , 2015 .

[27]  Anne Bowser,et al.  Building essential biodiversity variables (EBVs) of species distribution and abundance at a global scale , 2018, Biological reviews of the Cambridge Philosophical Society.

[28]  Y. Malhi,et al.  Modelling Amazonian forest eddy covariance data: a comparison of big leaf versus sun/shade models for the C-14 tower at Manaus I. Canopy photosynthesis , 2006 .

[29]  Onisimo Mutanga,et al.  Mapping spatial variability of foliar nitrogen in coffee (Coffea arabica L.) plantations with multispectral Sentinel-2 MSI data , 2018 .

[30]  Tadaki Hirose,et al.  Canopy Development and Leaf Nitrogen Distribution in a Stand of Carex Acutiformis , 1989 .

[31]  D. H. Card,et al.  Remote sensing of forest canopy and leaf biochemical contents , 1988 .

[32]  A. Skidmore,et al.  Leaf Area Index derivation from hyperspectral vegetation indicesand the red edge position , 2009 .

[33]  R. Kokaly,et al.  Characterizing canopy biochemistry from imaging spectroscopy and its application to ecosystem studies , 2009 .

[34]  Qiang Liu,et al.  Leaf Area Index , 2014 .

[35]  Andrew K. Skidmore,et al.  Retrieval of leaf water content spanning the visible to thermal infrared spectra , 2014 .

[36]  Anne Bowser,et al.  Building essential biodiversity variables(EBVs) of species distribution and abundanceat a global scale , 2017 .

[37]  M. Hill Vegetation index suites as indicators of vegetation state in grassland and savanna: An analysis with simulated SENTINEL 2 data for a North American transect , 2013 .

[38]  G. D’Urso,et al.  Experimental assessment of the Sentinel-2 band setting for RTM-based LAI retrieval of sugar beet and maize , 2009 .

[39]  A. Skidmore,et al.  Narrow band vegetation indices overcome the saturation problem in biomass estimation , 2004 .

[40]  M. Schaepman,et al.  Effects of woody elements on simulated canopy reflectance: Implications for forest chlorophyll content retrieval , 2010 .

[41]  Molly A Cavaleri,et al.  How vertical patterns in leaf traits shift seasonally and the implications for modeling canopy photosynthesis in a temperate deciduous forest. , 2016, Tree physiology.

[42]  A. Ramoelo,et al.  Water-removed spectra increase the retrieval accuracy when estimating savanna grass nitrogen and phosphorus concentrations , 2011 .

[43]  Clayton C. Kingdon,et al.  Spectroscopic determination of leaf morphological and biochemical traits for northern temperate and boreal tree species. , 2014, Ecological applications : a publication of the Ecological Society of America.

[44]  P. Curran Remote sensing of foliar chemistry , 1989 .

[45]  W. Dean Hively,et al.  Evaluating the relationship between biomass, percent groundcover and remote sensing indices across six winter cover crop fields in Maryland, United States , 2015, Int. J. Appl. Earth Obs. Geoinformation.

[46]  Philip Lewis,et al.  Hyperspectral remote sensing of foliar nitrogen content , 2012, Proceedings of the National Academy of Sciences.

[47]  M. Schaepman,et al.  Review of optical-based remote sensing for plant trait mapping , 2013 .

[48]  Josef Aschbacher,et al.  The European Earth monitoring (GMES) programme: Status and perspectives , 2012 .

[49]  Philip A. Townsend,et al.  Quantifying the influences of spectral resolution on uncertainty in leaf trait estimates through a Bayesian approach to RTM inversion , 2016 .

[50]  L. Carrascal,et al.  Partial least squares regression as an alternative to current regression methods used in ecology , 2009 .

[51]  J. Bryan Blair,et al.  Characterization of Canopy Layering in Forested Ecosystems Using Full Waveform Lidar , 2013, Remote. Sens..

[52]  Andrew K. Skidmore,et al.  Impact of Vertical Canopy Position on Leaf Spectral Properties and Traits across Multiple Species , 2018, Remote. Sens..

[53]  Anatoly A. Gitelson,et al.  Remote estimation of nitrogen and chlorophyll contents in maize at leaf and canopy levels , 2013, Int. J. Appl. Earth Obs. Geoinformation.

[54]  Jing M. Chen,et al.  Evaluation of leaf-to-canopy upscaling methodologies against carbon flux data in North America , 2012 .

[55]  A. Viña,et al.  Remote estimation of canopy chlorophyll content in crops , 2005 .

[56]  C. Saunders,et al.  Editor's comments: PLS: a silver bullet? , 2006 .

[57]  James F. Reynolds,et al.  Coordination theory of leaf nitrogen distribution in a canopy , 1993, Oecologia.

[58]  Pingheng Li,et al.  Canopy vertical heterogeneity plays a critical role in reflectance simulation , 2013 .

[59]  M. Cho,et al.  Assessing the effects of subtropical forest fragmentation on leaf nitrogen distribution using remote sensing data , 2013, Landscape Ecology.

[60]  Luis Alonso,et al.  Optimizing LUT-Based RTM Inversion for Semiautomatic Mapping of Crop Biophysical Parameters from Sentinel-2 and -3 Data: Role of Cost Functions , 2014, IEEE Transactions on Geoscience and Remote Sensing.

[61]  L. Poorter,et al.  Causes and consequences of variation in leaf mass per area (LMA): a meta-analysis. , 2009, The New phytologist.

[62]  Sean C. Thomas,et al.  A Reassessment of Carbon Content in Tropical Trees , 2011, PloS one.

[63]  Clement Atzberger,et al.  Estimation of vegetation LAI from hyperspectral reflectance data: Effects of soil type and plant architecture , 2008, Int. J. Appl. Earth Obs. Geoinformation.

[64]  N. Pettorelli,et al.  Essential Biodiversity Variables , 2013, Science.

[65]  Marco Heurich,et al.  Leaf Nitrogen Content Indirectly Estimated by Leaf Traits Derived From the PROSPECT Model , 2015, IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing.

[66]  Andrew K. Skidmore,et al.  Potential of Sentinel-2 spectral configuration to assess rangeland quality , 2015 .

[67]  M. Liddell,et al.  Canopy position affects the relationships between leaf respiration and associated traits in a tropical rainforest in Far North Queensland. , 2014, Tree physiology.

[68]  A. Savitzky,et al.  Smoothing and Differentiation of Data by Simplified Least Squares Procedures. , 1964 .

[69]  Andrew K. Skidmore,et al.  Retrieval of leaf area index in different plant species using thermal hyperspectral data , 2016 .

[70]  Lammert Kooistra,et al.  Trait Estimation in Herbaceous Plant Assemblages from in situ Canopy Spectra , 2013, Remote. Sens..