Construction Standard of Farmland Landscapeconstruction Standard of Farmland Landscape

  • Meichen Fu
  • Jianjun Zhang
Conference paper
Part of the IFIP Advances in Information and Communication Technology book series (IFIPAICT, volume 293)


Precision agriculture is an important choice for the future agriculture. It is the base for precision agriculture development to change the state of small-scale farmland production and weak agricultural foundation in China gradually. Combined with the poorness of village in China, the variation of farmland and the dominance of small-scale peasant economy, this paper analyzed the adaptability of farmland landscape pattern to precision agriculture based on literatures and farmland landscape survey. With the requirements of precision agricultural production, this paper put forward the standards on cultivated field scale and shape, farmland corridor structure, cultivated field matrix and farmland landscape protection in order to make farmland landscape suitable for precision agriculture and to provide references for the sustainable development of precision agriculture in China.


Paddy Field Precision Agriculture Construction Standard Land Consolidation Terrace Field 
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.


  1. Bai Yi. Shelterbelt construction based on precision information. Scientific and Technical Information of Soil and Water Conservation. 2007, (6):23–25. (in Chinese)Google Scholar
  2. Bao Haijun, Wu Cifang, Ye Yanmei,. Dimension design of farmland and application of GPS-GIS-RS technology to land consolidation. Transactions of the chinese society of agricultural engineering, 2002, 18(1):196–172.Google Scholar
  3. Chen Deen, Yang Fujiang. Demonstration application of precision agricultural technology in farm 852. Modernizing Agriculture, 2005, (4):40–41. (in Chinese)Google Scholar
  4. Chen Fang, Liu Dongbi, Wan Kaiyuan, Advances and perspective on site-specific nutrient management. Hubei agricultural sciences. 2006, 45(4):15–518.zbMATHGoogle Scholar
  5. Cœur D. L., Baudry J., Burel F., et al. Why and how we should study field boundary biodiversity in an agrarian landscape context. Agriculture, Ecosystems and Environment. 2002, 89(1–2):23–40.Google Scholar
  6. Croxton P. J., Carvell C., Mountford J. O., et al. A comparison of green lanes and field margins as bumblebee habitat in an arable landscape. Biological Conservation. 2002, 107(3):365–374.CrossRefGoogle Scholar
  7. Fu Meichen, Wang Jinman, Wang Guangjun. Land consolidation and reclamation. Beijing, Geological Publishing House, 2007. (in Chinese)Google Scholar
  8. General Administration of Land use, Ministry of Agriculture of People's Republic of China. Land use outline of agricultural producer's cooperative. Beijing, Financial & Economic Publishing House, 1956. (in Chinese)Google Scholar
  9. Lei Weiwei, Zhang Feng, Wang Yuanbo. Application of GPS technology to modern precision agriculture. Agricultural technology service. 25(3), pp. 113–115. (in Chinese)Google Scholar
  10. Lei Yu, Yuan Zhihua. Precision agriculture and its technical system. Journal of Henan Agricultural Sciences. 2007, (7):21–24. (in Chinese)Google Scholar
  11. Li Shicheng, Qin Laishou. Progress in the study of technology of precision agriculture variable fertilization. World Agriculture. 2007, (3):57–59. (in Chinese)Google Scholar
  12. Li Xintong, Zhu Hejian. Agro landscape changes and driving factors in coastal area of southeast Fujian: a case study of dananban farm. Resources Science. 2000, 22(1):35–39.Google Scholar
  13. Liu Yanxuan, Bai Huidong, Jiang Guiying. The research present condition and the development direction of precise agriculture in China. Chinese Agricultural Science Bulletin. 2007, 23(7):577–582.Google Scholar
  14. Roschewitz I., Thies C., Tscharntke T. Are landscape complexity and farm specialisation related to land-use intensity of annual crop fields. Agriculture, Ecosystems&Environment. 2005, 105(1–2):87–99.CrossRefGoogle Scholar
  15. Sui Changling, Cai Deli, Zhai Ruicheng,. Study on spatial variability of soil nutrients in the precision agriculture demonstration plot of Heilongjiang province. Journal of Heilongjiang August First Land Reclamation University. 2005, 17(5):28–32.Google Scholar
  16. Wang Maohua. Development of Precision Agriculture and Innovation of Engineering Technologies. Transactions of the chinese society of agricultural engineering. 1999, 15(1): 1–8.Google Scholar
  17. Wu Fei, Wang Yaosheng, Huang Yi. Water-soil quantitative assessment of protective precision agriculture system. Scientific and Technical Information of Soil and Water Conservation. 2006, (4):11–13. (in Chinese)Google Scholar
  18. Zhao Chunjiang, Xue Xuzhang, Wang Xiu,. Advance and prospects of precision agriculture technology system. Transactions of the chinese society of agricultural engineering. 2003, 19(4):7–12.Google Scholar
  19. Zhao Wei, Xie deben, Liu Hongbin, et al. Definition of proper sampling amount for soil nutrients analysis in precision agriculture. Chinese Journal of Eco-Agriculture. 2008, 16(2): 318–322.CrossRefGoogle Scholar
  20. Zhao Yanwen, Li Xuzheng, Jiang Fengqin,. Changes of farmland landscape patterns on landscape ecological mode: a case study of Yangzhong, Jiangsu. Jiangsu Agricultural Sciences. 2007, (5):256–258. (in Chinese)Google Scholar

Copyright information

© Springer Science+Business Media, LLC 2009

Authors and Affiliations

  1. 1.School of Land Sciences and TechnologyChina University of GeosciencesBeijingP. R.China
  2. 2.School of Land Sciences and TechnologyChina University of GeosciencesBeijingP. R.China

Personalised recommendations