Urban Remote Sensing. Группа авторов

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Urban Remote Sensing - Группа авторов


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      75 Pepe, M., Fregonese, L. and Scaioni, M. (2018) Planning airborne photogrammetry and remote‐sensing missions with modern platforms and sensors. European Journal of Remote Sensing, 51(1), 412–436.

      76 Plioutsias, A., Karanikas, N. and Chatzimihailidou, M.M. (2018) Hazard analysis and safety requirements for small drone operations: to what extent do popular drones embed safety? Risk Analysis: An International Journal, 38(3), 562–584.

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      86 Shafian, S., Rajan, N., Schnell, R. et al. (2018) Unmanned aerial systems‐based remote sensing for monitoring sorghum growth and development. PLoS ONE, 13(5), e0196605.

      87 Shan, S., Hou, Z. and Zhu, B. (2017) Albatross‐like utilization of wind gradient for unpowered flight of fixed‐wing aircraft. Applied Sciences, 7(10), 1061.

      88 Siebert, S. and Teizer, J. (2014) Mobile 3D mapping for surveying earthwork projects using an unmanned aerial vehicle (UAV) system. Automation in Construction, 41, 1–14.

      89 Singh, K.K. and Frazier, A.E. (2018) A meta‐analysis and review of unmanned aircraft system (UAS) imagery for terrestrial applications. International Journal of Remote Sensing, 39 (15–16), 5078–5098.

      90 Skrzypietz, B. (2012) Unmanned Aircraft Systems for Civilian Missions, Brandenburg Institute for Society and Security, Potsdam.

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      97 Torres‐Sánchez, J., López‐Granados, F., Borra‐Serrano, I. and Peña, J.M. (2018) Assessing UAV‐collected image overlap influence on computation time and digital surface model accuracy in olive orchards. Precision Agriculture, 19(1), 115–133.

      98 Toth, C., Jozkow, G. and Grejner‐Brzezinska, D. (2015) Mapping with small UAS: a point cloud accuracy assessment. Journal of Applied Geodesy, 9(4), 213–226.

      99 Trhan, O., Fraštia, M. and Marčiš, M. (2016) Building models created from UAV photogrammetry data. Proceedings of the International Multidisciplinary Scientific GeoConference SGEM, 2, 823–830.

      100 Tsouros, D.C., Bibi, S. and Sarigiannidis, P.G. (2019) A review on UAV‐based applications for precision agriculture. Information, 10 (11), 349.

      101 Turner, D., Lucieer, A. and Watson, C. (2012) An automated technique for generating georectified mosaics from ultra‐high resolution unmanned aerial vehicle (UAV) imagery, based on structure from motion (SfM) point clouds. Remote Sensing, 4(5), 1392–1410.

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      103 Wallace, P., Martin, R. and White, I. (2018) Keeping pace with technology: drones, disturbance and policy deficiency. Journal of Environmental Planning & Management, 61(7), 1271–1288.

      104 Watkins, S., Burry, J., Mohamed, A. et al. (2020) Ten questions concerning the use of drones in urban environments. Building and Environment, 167, 106458.

      105 West, J. and Bowman, J. (2016) The domestic use of drones: an ethical analysis of surveillance issues. Public Administration Review, 76(4), 649–659.

      106 Wu, Y. and An, Z. (2019) UAV route planning for image 3D reconstruction. Dianzi Jishu Yingyong, 45(3), 76–79.

      107 Wurm, M., Taubenböck, H., Weigand, M. and Schmitt, A. (2017) Slum mapping in polarimetric SAR data using spatial features. Remote Sensing of Environment, 194, 190–204.

      108 Yao, H., Qin, R. and Chen, X. (2019) Unmanned aerial vehicle for remote sensing applications—a review. Remote Sensing, 11 (12), 1443.

      109 Zarco‐Tejada, P., González‐Dugo, V. and Berni, J.A.J. (2012) Fluorescence, Temperature and Narrow‐Band Indices Acquired from a UAV Platform for Water Stress Detection


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