The winter wheat aboveground biomass is an important agronomic parameter to estimate the growth status, and evaluate the yield and quality. Spectrum technique provides a nondestructive and fast method for estimating the winter wheat biomass. In order to find the optimum model by analyzing the wheat canopy spectral characteristic during the whole growth period, field trails were conducted at the National Demonstration Base of Precision Agriculture in Beijing Xiaotangshan town. A portable spectrometer (200-1100 nm) was used to collect the wheat canopy spectra of different varieties at the different growth stages (green stage, jointing stage, booting stage, heading stage and filling stage), clipping the winter wheat at ground level at the same time. Regression and correlation analysis were used to establish the winter wheat biomass estimation models in this study. The results showed that the biggest different bands of the winter wheat canopy spectral reflection curves mainly lied along the blue and near-infrared bands. The spectral reflectance at 678 nm in the visible light range had the best correlation with the biomass (correlation=0.724). The monadic regression analysis, the multiple regression analysis and the partial least squares regression analysis were applied to establish the biomass estimation models, among which the partial least squares regression (PLS) model had higher modeling precision. The R2 of the calibration and validation were 0.916 and 0.911, respectively. The root-mean-square error (RMSE) of the calibration and validation were 0.090 kg and 0.094 kg (Sample area 50 cm×60 cm). The results indicated that the PLS model (400-1000 nm) could fully estimate the aboveground biomass in the whole growth period of wheat with a better measurement accuracy.
Keywords: winter wheat, biomass, canopy spectra, crop growth period, partial least square regression
DOI: 10.3965/j.ijabe.20150806.1311

Citation: Zheng L, Zhu D Z, Liang D, Zhang B H, Wang C, Zhao C J. Winter wheat biomass estimation based on canopy spectra. Int J Agric & Biol Eng, 2015; 8(6): 30－36.

winter wheat, biomass, canopy spectra, crop growth period, partial least square regression

Lukina E V, Freeman K W, Wynn K J, Thomason W E, Mullen R W, Stone M L, et al. Nitrogen fertilization optimization algorithm based on in-season estimates of yield and plant nitrogen uptake. Journal of Plant Nutrition, 2001; 24(6): 885−898.

Clevers J G P W, van der Heijden G W A M, Verzakov S, Schaepman M E. Estimating grassland biomass using SVM band shaving of hyperspectral data. Photogrammetric Engineering and Remote Sensing, 2007; 73(10): 1141−1148..

Haboudane D, Miller J R, Pattey E, Zarco-Tejada P J, Strachan I B. Hyperspectral vegetation indices and novel algorithms for predicting green LAI of crop canopies: Modeling and validation in the context of precision agriculture. Remote Sensing of Environment, 2004; 90(3): 337−352.

Leprieur C, Kerr Y H, Mastorchio S, Meunier J C. Monitoring vegetation cover across semi-arid regions: comparison of remote observations from various scales. International Journal of Remote Sensing, 2000; 21(2):

−300.

Thomas V, Treitz P, Mccaughey J H, Noland T, Rich L. Canopy chlorophyll concentration estimation using hyperspectral and lidar data for a boreal mixedwood forest in northern Ontario, Canada. International Journal of Remote Sensing, 2008; 29(4): 1029−1052.

Madugundu R, Nizalapur V, Jha C S. Estimation of LAI and above-ground biomass in deciduous forests: Western Ghats of Karnataka, India. International Journal of Applied Earth Observation and Geoinformation, 2008; 10(2): 211−219.

Jin X L, Xu X G, Li Z H, Wang Q, Wang Y, Li C J,et al. Estimation of Winter Wheat Protein Content Based on New Indexes. Spectroscopy and Spectral Analysis, 2013; 33(9): 2541−2545.

Filella I, Penuelas J. The red edge position and shape as indicators of plant chlorophyll content, biomass and hydric status. International Journal of Remote Sensing, 1994; 15(7): 1459−1470.

Tang Y L, Wang X Z, Wang F M, Wang R C. Study on the determination of LAI and biomass of crop by hyperspectral. Journal of Northwest A&F University: Natural Science Edition, 2004; 32(11): 100−104. (in Chinese with English abstract)

Hansen P M, Schjoerring J K. Reflectance measurement of canopy biomass and nitrogen status in wheat crops using normalized difference vegetation indices and partial least squares regression. Remote Sensing of Environment, 2003; 86(4): 542−553.

Casanova D, Epema G F, Goudriaan J. Monitoring rice reflectance at field level for estimating biomass and LAI. Field Crops Research, 1998; 55(1): 83−92.

Wang D C, Wang J H, Jin N, Wang Q, Li C J, Huang J F, et al. ANN-based wheat biomass estimation using canopy hyperspectral vegetation. Transactions of the CSAE, 2008; 24(Supp.2): 196−201. (in Chinese with English abstract)

Song K S, Zhang B, Li F, Duan H T, Wang Z M. Correlative analyses of hyperspectral reflectance, soybean LAI and abo veg round biomass. Transactions of the CSAE, 2005; 21(1): 36−40. (in Chinese with English abstract)

Fu Y Y, Wang J H, Yang G J, Song X Y, Xu X G, Feng H K. Band depth analysis and partial least square regression based winter wheat biomass estimation using hyperspectral measurements. Spectroscopy and Spectral Analysis, 2013; 32(5): 1315−1319.

Sun H, Li M Z, Zhao Y, Zhang Y E, Wang X M, et al. The spectral characteristics and chlorophyll content at winter wheat growth stages. Spectroscopy and Spectral Analysis, 2010; (1): 192−196.

Zhang J, Zhang J. Response of winter wheat spectral reflectance to leaf chlorophyll, total nitrogen of above ground. Chinese Journal of Soil Science, 2008, 39(3): 586−592. (in Chinese with English abstract)

Yao F Q, Cai H J, Wang H J, Zhang Q, Wang J. Correlation between percentage vegetation cover and hyperspectral characteristics of winter wheat. Transactions of the CSAM, 2012; 43(7): 156−162. (in Chinese with English abstract)

Hou X H, Niu Z, Huang N, Xu S G. The Hyperspectral remote sensing estimation models of total biomass and true LAI of wheat. Remote Sensing for Land & Resources,

; 24(4): 30−35.

Fu Y Y, Yang G J, Wang J H, Song X Y, Feng H K. Winter wheat biomass estimation based on spectral indices, band depth analysis and partial least squares regression using hyperspectral measurements. Computers and Electronics in Agriculture, 2014; 100(1): 51−59.

Hansen P M, Schjoerring J K. Reflectance measurement of canopy biomass and nitrogen status in wheat crops using normalized difference vegetation indices and partial least squares regression. Remote Sensing of Environment, 2003; 86(4): 542−553.