Estimating Biomass of Native Grass Grown under Complex Management Treatments Using WorldView-3 Spectral Derivatives

The ability of texture models and red-edge to facilitate the detection of subtle structural vegetation traits could aid in discriminating and mapping grass quantity, a challenge that has been longstanding in the management of grasslands in southern Africa. Subsequently, this work sought to explore the robustness of integrating texture metrics and red-edge in predicting the above-ground biomass of grass growing under different levels of mowing and burning in grassland management treatments. Based on the sparse partial least squares regression algorithm, the results of this study showed that red-edge vegetation indices improved above-ground grass biomass from a root mean square error of perdition (RMSEP) of 0.83 kg/m2 to an RMSEP of 0.55 kg/m2. Texture models further improved the accuracy of grass biomass estimation to an RMSEP of 0.35 kg/m2. The combination of texture models and red-edge derivatives (red-edge-derived vegetation indices) resulted in an optimal prediction accuracy of RMSEP 0.2 kg/m2 across all grassland management treatments. These results illustrate the prospect of combining texture metrics with the red-edge in predicting grass biomass across complex grassland management treatments. This offers the detailed spatial information required for grassland policy-making and sustainable grassland management in data-scarce regions such as southern Africa.

[1]  B. Minasny,et al.  Mapping and identifying basal stem rot disease in oil palms in North Sumatra with QuickBird imagery , 2011, Precision Agriculture.

[2]  T. O’Connor,et al.  Determinants of community organization of a South African mesic grassland , 2005 .

[3]  Onisimo Mutanga,et al.  High density biomass estimation for wetland vegetation using WorldView-2 imagery and random forest regression algorithm , 2012, Int. J. Appl. Earth Obs. Geoinformation.

[4]  G. Fitzgerald,et al.  Measuring and predicting canopy nitrogen nutrition in wheat using a spectral index—The canopy chlorophyll content index (CCCI) , 2010 .

[5]  K. O. Niemann,et al.  Simulated impact of sample plot size and co-registration error on the accuracy and uncertainty of LiDAR-derived estimates of forest stand biomass , 2011 .

[6]  Akira Iwasaki,et al.  Optimal Wavelength Selection on Hyperspectral Data with Fused Lasso for Biomass Estimation of Tropical Rain Forest , 2016 .

[7]  A. Huete,et al.  A review of vegetation indices , 1995 .

[8]  Mauricio Galleguillos,et al.  Predicting Vascular Plant Richness in a Heterogeneous Wetland Using Spectral and Textural Features and a Random Forest Algorithm , 2016, IEEE Geoscience and Remote Sensing Letters.

[9]  Anatoly A. Gitelson,et al.  NON-DESTRUCTIVE AND REMOTE SENSING TECHNIQUES FOR ESTIMATION OF VEGETATION STATUS , 2001 .

[10]  P. Atkinson,et al.  Relating SAR image texture to the biomass of regenerating tropical forests , 2005 .

[11]  Sandra Eckert,et al.  Improved Forest Biomass and Carbon Estimations Using Texture Measures from WorldView-2 Satellite Data , 2012, Remote. Sens..

[12]  O. Mutanga,et al.  Investigating the robustness of the new Landsat-8 Operational Land Imager derived texture metrics in estimating plantation forest aboveground biomass in resource constrained areas , 2015 .

[13]  M. Pärtel,et al.  Plant species richness: the world records , 2012 .

[14]  Mario Chica-Olmo,et al.  Computing geostatistical image texture for remotely sensed data classification , 2000 .

[15]  J. Peñuelas,et al.  The red edge position and shape as indicators of plant chlorophyll content, biomass and hydric status. , 1994 .

[16]  Onisimo Mutanga,et al.  Discriminating Rangeland Management Practices Using Simulated HyspIRI, Landsat 8 OLI, Sentinel 2 MSI, and VENµS Spectral Data , 2016, IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing.

[17]  R. Lucas,et al.  A review of remote sensing technology in support of the Kyoto Protocol , 2003 .

[18]  Yong Pang,et al.  Mapping Aboveground Biomass using Texture Indices from Aerial Photos in a Temperate Forest of Northeastern China , 2016, Remote. Sens..

[19]  Martin Brandt,et al.  Do Red Edge and Texture Attributes from High-Resolution Satellite Data Improve Wood Volume Estimation in a Semi-Arid Mountainous Region? , 2016, Remote. Sens..

[20]  Linjing Zhang,et al.  Improved model for estimating the biomass of Populus euphratica forest using the integration of spectral and textural features from the Chinese high-resolution remote sensing satellite GaoFen-1 , 2015 .

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

[22]  O. Mutanga,et al.  A comparison of partial least squares (PLS) and sparse PLS regressions for predicting yield of Swiss chard grown under different irrigation water sources using hyperspectral data , 2014 .

[23]  Compton J. Tucker,et al.  A critical review of remote sensing and other methods for non-destructive estimation of standing crop biomass , 1980 .

[24]  Lei Zhang,et al.  A comparison of two models with Landsat data for estimating above ground grassland biomass in Inner Mongolia, China , 2009 .

[25]  Luis Alonso,et al.  How Universal Is the Relationship between Remotely Sensed Vegetation Indices and Crop Leaf Area Index? A Global Assessment , 2016, Remote. Sens..

[26]  D. Lu Aboveground biomass estimation using Landsat TM data in the Brazilian Amazon , 2005 .

[27]  S. I. Pogosyan,et al.  Application of Reflectance Spectroscopy for Analysis of Higher Plant Pigments , 2003, Russian Journal of Plant Physiology.

[28]  Chengquan Huang,et al.  Quantifying Live Aboveground Biomass and Forest Disturbance of Mountainous Natural and Plantation Forests in Northern Guangdong, China, Based on Multi-Temporal Landsat, PALSAR and Field Plot Data , 2016, Remote. Sens..

[29]  Nicolas Barbier,et al.  Aboveground biomass mapping of African forest mosaics using canopy texture analysis: toward a regional approach. , 2014, Ecological applications : a publication of the Ecological Society of America.

[30]  O. Mutanga,et al.  Examining the potential of Sentinel-2 MSI spectral resolution in quantifying above ground biomass across different fertilizer treatments , 2015 .

[31]  Y. Ouma,et al.  Analysis of co‐occurrence and discrete wavelet transform textures for differentiation of forest and non‐forest vegetation in very‐high‐resolution optical‐sensor imagery , 2008 .

[32]  Alan K. Knapp,et al.  Responses to fire differ between South African and North American grassland communities , 2014 .

[33]  R. Brandl,et al.  Contrasting performance of Lidar and optical texture models in predicting avian diversity in a tropical mountain forest , 2016 .

[34]  Guangxing Wang,et al.  Examining Spectral Reflectance Saturation in Landsat Imagery and Corresponding Solutions to Improve Forest Aboveground Biomass Estimation , 2016, Remote. Sens..

[35]  J. Dungan,et al.  Exploring the relationship between reflectance red edge and chlorophyll content in slash pine. , 1990, Tree physiology.

[36]  N. Broge,et al.  Comparing prediction power and stability of broadband and hyperspectral vegetation indices for estimation of green leaf area index and canopy chlorophyll density , 2001 .

[37]  J. Nichol,et al.  Improved forest biomass estimates using ALOS AVNIR-2 texture indices , 2011 .

[38]  G. Asner Biophysical and Biochemical Sources of Variability in Canopy Reflectance , 1998 .

[39]  R. H. Groves,et al.  Time of mowing and burning veld : Short term effects on production and tiller development , 1977 .

[40]  K. Paustian,et al.  GRASSLAND MANAGEMENT AND CONVERSION INTO GRASSLAND: EFFECTS ON SOIL CARBON , 2001 .

[41]  Alfredo Huete,et al.  Separation of soil-plant spectral mixture by factor analysis , 1986 .

[42]  S. Keleş,et al.  Sparse partial least squares regression for simultaneous dimension reduction and variable selection , 2010, Journal of the Royal Statistical Society. Series B, Statistical methodology.

[43]  C. Dibari,et al.  Satellite estimate of grass biomass in a mountainous range in central Italy , 2003, Agroforestry Systems.

[44]  D. Timothy,et al.  Quantifying aboveground biomass in African environments : A review of the trade-offs between sensor estimation accuracy and costs , 2016 .

[45]  Ruiliang Pu,et al.  Extraction of red edge optical parameters from Hyperion data for estimation of forest leaf area index , 2003, IEEE Trans. Geosci. Remote. Sens..

[46]  Andrew K. Skidmore,et al.  Estimation of green grass/herb biomass from airborne hyperspectral imagery using spectral indices and partial least squares regression , 2007, Int. J. Appl. Earth Obs. Geoinformation.

[47]  Andrew K. Skidmore,et al.  Regional estimation of savanna grass nitrogen using the red-edge band of the spaceborne RapidEye sensor , 2012, Int. J. Appl. Earth Obs. Geoinformation.

[48]  Tawanda W. Gara,et al.  Predicting forest carbon stocks from high resolution satellite data in dry forests of Zimbabwe: exploring the effect of the red-edge band in forest carbon stocks estimation , 2016 .

[49]  Edward M. Barnes,et al.  Remote Sensing of Cotton Nitrogen Status Using the Canopy Chlorophyll Content Index (CCCI) , 2008 .

[50]  Valério D. Pillar,et al.  Grassland degradation and restoration: a conceptual framework of stages and thresholds illustrated by southern Brazilian grasslands , 2015 .

[51]  J A Griffith,et al.  A Multivariate Analysis of Biophysical Parameters of Tallgrass Prairie Among Land Management Practices and Years , 2001, Environmental monitoring and assessment.

[52]  Janet E. Nichol,et al.  Improved Biomass Estimation Using the Texture Parameters of Two High-Resolution Optical Sensors , 2011, IEEE Transactions on Geoscience and Remote Sensing.

[53]  Onisimo Mutanga,et al.  Assessment of the Contribution of WorldView-2 Strategically Positioned Bands in Bracken fern (Pteridium aquilinum (L.) Kuhn) Mapping , 2014 .

[54]  P. Gong,et al.  Comparison of IKONOS and QuickBird images for mapping mangrove species on the Caribbean coast of Panama , 2004 .

[55]  A. Gitelson,et al.  Remote estimation of chlorophyll content in higher plant leaves , 1997 .

[56]  Hormoz Sohrabi,et al.  ABILITY OF LANDSAT-8 OLI DERIVED TEXTURE METRICS IN ESTIMATING ABOVEGROUND CARBON STOCKS OF COPPICE OAK FORESTS , 2016 .

[57]  Onisimo Mutanga,et al.  Testing the capabilities of the new WorldView-3 space-borne sensor’s red-edge spectral band in discriminating and mapping complex grassland management treatments , 2017 .

[58]  D. Lu The potential and challenge of remote sensing‐based biomass estimation , 2006 .

[59]  José F. Moreno,et al.  rown and green LAI mapping through spectral indices , 2014 .

[60]  Jason C. Neff,et al.  Estimates of Aboveground Biomass from Texture Analysis of Landsat Imagery , 2014, Remote. Sens..

[61]  Alan H. Strahler,et al.  Measuring Effective Leaf Area Index, Foliage Profile, and Stand Height in New England Forest Stands Using a Full-Waveform Ground-Based Lidar , 2011 .

[62]  M. T. Mentis,et al.  The Effect of Fire on Forage Production and Quality , 1984 .

[63]  G. Foody,et al.  Estimating tropical forest biomass with a combination of SAR image texture and Landsat TM data: An assessment of predictions between regions , 2012 .

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

[65]  Priyakant Sinha,et al.  Review of the use of remote sensing for biomass estimation to support renewable energy generation , 2015 .

[66]  Eric Ariel L. Salas,et al.  Multispectral and Texture Feature Application in Image-Object Analysis of Summer Vegetation in Eastern Tajikistan Pamirs , 2016, Remote. Sens..

[67]  Robert M. Haralick,et al.  Textural Features for Image Classification , 1973, IEEE Trans. Syst. Man Cybern..

[68]  Alfonso Fernández-Manso,et al.  SENTINEL-2A red-edge spectral indices suitability for discriminating burn severity , 2016, Int. J. Appl. Earth Obs. Geoinformation.

[69]  F. O'Mara The role of grasslands in food security and climate change. , 2012, Annals of botany.

[70]  Arnon Karnieli,et al.  redicting forest structural parameters using the image texture derived from orldView-2 multispectral imagery in a dryland forest , Israel , 2011 .

[71]  Shogoro Fujiki,et al.  Estimation of the stand ages of tropical secondary forests after shifting cultivation based on the combination of WorldView-2 and time-series Landsat images , 2016 .

[72]  A. Huete A soil-adjusted vegetation index (SAVI) , 1988 .

[73]  Onisimo Mutanga,et al.  Forage quality of savannas - Simultaneously mapping foliar protein and polyphenols for trees and grass using hyperspectral imagery , 2010 .