Zhang Pan, Wang Kejian, Lyu Qiang, He Shaolan, Yi Shilai, Xie Rangjin, Zheng Yongqiang, Ma Yanyan, and Deng Lie


  1. [1] M. Atiq, M.A. Khan, S.T. Sahi, and R. Ahmad, Genetic response of citrus germplasm against citrus leafminer, Journal of Animal and Plant Sciences, 23(1), 2013, 240–243.
  2. [2] M.M. Mckenna, E.M.A.F. Hammad, and M.T. Farran, Effect of Melia azedarach (Sapindales: Meliaceae) fruit extracts on citrus leafminer Phyllocnistis citrella (Lepidoptera: Gracillariidae), SpringerPlus, 2(1) 2013, 144.
  3. [3] J. Belasque Jr., A.L. Parra-Pedrazzoli, N.J. Rodrigues, et al., Adult citrus leafminers (Phyllocnistis citrella) are not efficient vectors for Xanthomonas axonopodis pv. Citri, Plant Disease, 89 (6), 2005, 590–594.
  4. [4] G.P. Bernet, C. Margaix, J. Jacas, E.A. Carbonell, and M.J. Asins, Genetic analysis of citrus leafminer susceptibility, Theoretical and Applied Genetics, 110(8), 2005, 1393–1400.
  5. [5] J.C. Legaspi, J.V. French, A.G. Zuniga, and B.C. Legaspi, Population dynamics of the citrus leafminer, Phyllocnistis citrella (Lepidoptera: Gracillariidae), and its natural enemies in Texas and Mexico, Biological Control, 21(1), 2001, 84–90.
  6. [6] A. Raga, M.E. Satol, M.F. Souza, and R.C. Siloto, Comparison of spray insecticides against citrus leafminer, Arquivos Do Instituto Biologico (Sao Paulo), 68, 2001, 77–82.
  7. [7] X.N. Zeng, M.L. Wu, S. Luo, and S.H. Zhao, Role of three botanical insecticides on the control of citrus leafminer (Phyllocnistis citrella Stainton), Acta Universitatis Agriculturalis Boreali-occidentalis, 29 (6), 2000, 54–56.
  8. [8] M.E. Rogers and P.A. Stansly, Florida citrus pest management guidelines: Asian citrus psyllid and citrus leafminer, Florida Cooperative Extension Service, Institute of Food and Agricultural Sciences, University of Florida, ENY-734, 2007.
  9. [9] M. Mustafa, M. Imran, A. Rasool, M. Azeem, A. Riaz, and M. Afzal, Evaluation of commercial citrus cultivars for resistance to citrus leaf miner and its management, Journal of Entomology and Zoology Studies, 2(6), 2014, 213–216.
  10. [10] R.S.C. Christiano, M. Dalla Pria, W.C. Jesus Junior, J.R.P. Parra, L. Amorim, and A. Bergamin Filho, Effect of the citrus leaf-miner damage, mechanical damage and inoculum concentration on severity of symptoms of Asiatic citrus canker in Tahiti lime, Crop Protection, 26(2), 2007, 59–65.
  11. [11] W.C. Jesus Jr., J. Belasque Jr., L. Amorim, R.S.C. Christiano, J.R.P. Parra, and A. Bergamin Filho, Injuries caused by citrus leaf miner (Phyllocnistis citrella) exacerbate citrus canker (Xanthomonas axonopodis pv. citri) infection, Fitopatologia Brasileira, 31(3), 2006, 277–283.
  12. [12] H.F. Zang and L.Y. Xu, Summary of research status on orchard sprayer, Journal of Chinese Agricultural Mechanization, 35(3), 2014, 112–118.
  13. [13] W. Qiu, W.M. Ding, X.M. Fu, X.C. Wang, X.L. Lyu, and Y.N. Li, Design and experiment of ring double-channel fan for spraying machine in orchard, Transactions of the Chinese Society Agricultural Engineering, 28(12), 2012, 13–17.
  14. [14] X.K. He, Improving severe draggling actuality of plant protection machinery and its application techniques, Transactions of the Chinese Society Agricultural Engineering, 20(1), 2004, 13–15.
  15. [15] X.M. Fu, X.L. Lyu, W.M. Ding, P. Wu, S.M. Ding, and W. Qiu, Present state and technical requirement about plant protection machinery in China, Chinese Agricultural Mechanization, (6), 2009, 10–13, 17.
  16. [16] S.R. Song, T.S. Hong, D.Z. Sun, Y.Q. Zhu, and X.D. Peng, Droplet deposition in variable-speed spraying experiment of air blast sprayer, Journal of Agricultural Mechanization Research, 31(1), 2009, 166–169.
  17. [17] Z.Y. Zhou, Y. Zang, X.W. Luo, Y.B. Lan, and X.Y. Xue, Technology innovation development strategy on agricultural aviation industry for plant protection in China, Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 29(24), 2013, 1–10.
  18. [18] Y. Huang, W.C. Hoffmann, Y.B. Lan, W. Wu, and B.K. Fritz, Development of a spray system an unmanned aerial vehicle platform, Applied Engineering Agriculture, 25(6), 2009, 803–809.
  19. [19] X.Y. Xue, K. Tu, W.C. Qin, Y.B. Lan, and H.H. Zhang, Drift and deposition of ultra-low altitude and low volume application in paddy field, International Journal of Agricultural and Biological Engineering, 7(4), 2014, 23–28.
  20. [20] Y.B. Huang, S.J. Thomson, W.C. Hoffmann, Y.B. Lan, and B.K. Fritz, Development and prospect of unmanned aerial vehicle technologies for agricultural production management, International Journal of Agricultural and Biological Engineering, 6(3), 2013, 1–10.
  21. [21] H.J. Asl, G. Oriolo, and H. Bolandi, An adaptive scheme for image-based visual servoing of an underactuated UAV, International Journal of Robotics and Automation, 29(1), 2014, 92–104.
  22. [22] C. Kownacki, Successful application of miniature laser rangefinders in obstacle avoidance method for fixed wing MAV, International Journal of Robotics and Automation, 28(3), 2013, 292–298.
  23. [23] T. Chettibi, Generating near-optimal reference trajectories for small fixed-wing UAVs, International Journal of Robotics and Automation, 26(2), 2011, 187.
  24. [24] B.S. Fai¸cal, F.G. Costa, G. Pessin, et al., The use of unmanned aerial vehicles and wireless sensor networks for spraying pesticides, Journal of Systems Architecture, 60(4), 2014, 393–404.
  25. [25] Y. Huang, W.C. Hoffman, Y.B. Lan, B.K. Fritz, and S.J. Thomson, Development of a low-volume sprayer for an unmanned helicopter, Journal of Agricultural Science, 7(1), 2014, 148–153.
  26. [26] D.Y. Zhang, L.P. Chen, R.R. Zhang, et al., Evaluating effective swath width and droplet distribution of aerial spraying systems on M-18B and Thrush 510G airplanes, International Journal of Agricultural and Biological Engineering, 8(2), 2015, 21–30.
  27. [27] H. Jiang, GB/T 17980.58-2004, Pesticide–Guidelines for the field efficacy trials (II)–Part 58: Insecticides against leaf-miner on citrus [S]. Beijing: China Standard Press, 2004.
  28. [28] P. Zhang, Q. Lyu, S.L. He, et al., Effects of citrus treeshape and spraying height of small unmanned aerial vehicle on droplet distribution, International Journal of Agricultural and Biological Engineering, 9(4), 2016, 45–52.
  29. [29] H. Zhang, Researches on relationship between the photosynthesis, canopy, and fruit quality of different shapes in citrus, Wuhan: Huazhong Agricultural University, 2012.
  30. [30] L. Le´on, R. De La Rosa, L. Rallo, N. Guerrero, and D. Barranco, Influence of spacing on the initial production of hedgerow-shaped ‘Arbequina’olive orchards, Spanish Journal of Agricultural Research, 5(4), 2013, 554–558.
  31. [31] E.R. Trentacoste, D.J. Connor, and M. G´omez-del-Campo, Effect of olive hedgerow-shaped orientation on vegetative growth, fruit characteristics and productivity, Scientia Horticulturae, 192, 2015, 60–69.
  32. [32] S.U. Cherbiy-Hoffmann, P.S. Searles, A.J. Hall, and M.C. Rousseaux, Influence of light environment on yield determinants and components in large olive hedgerow-shaped following mechanical pruning in the subtropics of the Southern Hemisphere, Scientia Horticulturae, 137, 2012, 36–42.
  33. [33] Y. Ru, H.P. Zhou, and C.R. Shu, Deposition evaluation of aerial electrostatic spraying system assembled in fixed-wing, Applied Engineering in Agriculture, 30(5), 2014, 751–757.
  34. [34] C.R. Shu, H.Y. Pan, H.P. Zhou, et al., Deposition effects of electrostatic and non-electrostatic aerial spray, Scientia Silvae Sinicae, 48(4), 2012, 75–80.
  35. [35] L. Xu, H. Zhu, H.E. Ozkan, W.E. Bagley, and C.R. Krause, Droplet evaporation and spread on waxy and hairy leaves associated with type and concentration of adjuvants, Pest Management Science, 67(7), 2011, 842–851.
  36. [36] H.Z. Yuan, Z.Q. Wang, R.H. Sun, S.F. Li, Z. Dong, and L.P. Sun, Influences of nozzle type and spray adjuvant on the distribution of spray droplets with stretcher mounted sprayer in peach orchards, Plant Protection, 36(1), 2010, 106–109.
  37. [37] D. Nuyttens, K. Baetens, M. De Schampheleire, and B. Sonck, Effect of nozzle type, size and pressure on spray droplet characteristics, Biosystems Engineering, 97(3), 2007, 333–345.
  38. [38] R. Xu, L.X. Li, L.Q. Zhang, B.W. Zhu, X. Liu, and X.B. Bu, Influence of pressure and surface roughness on the heat transfer efficiency during water spray quenching of 6082 aluminum alloy, Journal of Materials Processing Technology, 214(12), 2014, 2877–2883.

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