The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences (Aug 2013)

Very high resolution crop surface models (CSMs) from UAV-based stereo images for rice growth monitoring In Northeast China

  • J. Bendig,
  • M. Willkomm,
  • N. Tilly,
  • M. L. Gnyp,
  • S. Bennertz,
  • C. Qiang,
  • C. Qiang,
  • Y. Miao,
  • Y. Miao,
  • V. I. S. Lenz-Wiedemann,
  • V. I. S. Lenz-Wiedemann,
  • G. Bareth,
  • G. Bareth

DOI
https://doi.org/10.5194/isprsarchives-XL-1-W2-45-2013
Journal volume & issue
Vol. XL-1-W2
pp. 45 – 50

Abstract

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Unmanned aerial vehicles (UAVs) became popular platforms for the collection of remotely sensed geodata in the last years (Hardin & Jensen 2011). Various applications in numerous fields of research like archaeology (Hendrickx et al., 2011), forestry or geomorphology evolved (Martinsanz, 2012). This contribution deals with the generation of multi-temporal crop surface models (CSMs) with very high resolution by means of low-cost equipment. The concept of the generation of multi-temporal CSMs using Terrestrial Laserscanning (TLS) has already been introduced by Hoffmeister et al. (2010). For this study, data acquisition was performed with a low-cost and low-weight Mini-UAV (http://www.mikrokopter.de) which was equipped with the high resolution Panasonic Lumix GF3 12 megapixel consumer camera. The self-built and self-maintained system has a payload of up to 1 kg and an average flight time of 15 minutes. The maximum speed is around 30 km/h and the system can be operated up to a wind speed of less than 19 km/h (Beaufort scale number 3 for wind speed). Using a suitable flight plan stereo images can be captured. For this study, a flying height of 50 m and a 44% side and 90% forward overlap was chosen. The images are processed into CSMs under the use of the Structure from Motion (SfM)-based software Agisoft Photoscan 0.9.0. The resulting models have a resolution of 0.02 m and an average number of about 12 million points. Further data processing in Esri ArcGIS allows for quantitative comparison of the plant heights. The multi-temporal datasets are analysed on a plot size basis. The results can be compared to and combined with the additional field data. Detecting plant height with non-invasive measurement techniques enables analysis of its correlation to biomass and other crop parameters (Hansen & Schjoerring, 2003; Thenkabail et al., 2000) measured in the field. The method presented here can therefore be a valuable addition for the recognition of such correlations.