论文信息 - Evaluation of a UAV-based hyperspectral frame camera for monitoring the leaf nitrogen concentration in rice

Evaluation of a UAV-based hyperspectral frame camera for monitoring the leaf nitrogen concentration in rice

UAV based hyperspectral imaging is a promising approach to monitor crop growth status rapidly and non-destructively. This paper described a novel instrument to get hyperspectral information from lightweight unmanned aerial vehicles for crop monitoring. The objectives of this study were to assess the data quality of one hyperspectral frame camera and evaluate the ability in rice nitrogen status monitoring. In this study, we introduced one hyperspectral frame camera weighing 470g which could be mounted to low-weight UAVs (<;3 kg). The flight campaign was conducted in a paddy rice field in September 2015. During the flight, two ground-based portable spectrometers (ASD Field Spec Pro spectrometer and GreenSeeker RT 100) were used to collect rice canopy spectra. Later, Normalized difference vegetation index (NDVI) derived from hyperspectral images was compared with that from GreenSeeker and ASD. Also, field sampling was taken at the same day with the flight, and leaf nitrogen concentration (LNC) was obtained through Kjeldahl digestion method. Five existing vegetation indices that were used for N detection were used to estimate LNC. Results are satisfactory, which lay a foundation for the promising application of UAV-based hyperspectral remote sensing on precision agriculture.

[1] Pablo J. Zarco-Tejada,et al. Airborne Hyperspectral Images and Ground-Level Optical Sensors As Assessment Tools for Maize Nitrogen Fertilization , 2014, Remote. Sens..

[2] Xia Yao,et al. Monitoring leaf nitrogen status with hyperspectral reflectance in wheat , 2008 .

[3] Z. Niu,et al. Estimation of leaf biochemical content using a novel hyperspectral full-waveform LiDAR system , 2014 .

[4] K. H. Ryu,et al. Fertiliser application performance of a variable-rate pneumatic granular applicator for rice production , 2008 .

[5] G. G. Stokes. "J." , 1890, The New Yale Book of Quotations.

[6] John Shepanski,et al. Hyperion, a space-based imaging spectrometer , 2003, IEEE Trans. Geosci. Remote. Sens..

[7] Weixing Cao,et al. Common Spectral Bands and Optimum Vegetation Indices for Monitoring Leaf Nitrogen Accumulation in Rice and Wheat , 2012 .

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

[9] W. Marsden. I and J , 2012 .

[10] Xin-ping Chen,et al. Reducing environmental risk by improving N management in intensive Chinese agricultural systems , 2009, Proceedings of the National Academy of Sciences.

[12] J. Eitel,et al. Using in‐situ measurements to evaluate the new RapidEye™ satellite series for prediction of wheat nitrogen status , 2007 .

[13] D. Walvoort,et al. A linear model to predict with a multi‐spectral radiometer the amount of nitrogen in winter wheat , 2006 .