[Studies in Computational Intelligence 481] Artur Babiarz, Robert Bieda, Karol Jędrasiak, Aleksander Nawrat (auth.), Aleksander Nawrat, Zygmunt Kuś (eds.) - Vision Based Systemsfor UAV Applications (2013, Sprin

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74 Z. Kuś and A. Nawrat 5 Summary This chapter has presented a solution of the camera head control problem. It allows to track objects in rapid disturbance conditions. The paper assumes that the object moves considerably slower than UAV during autonomous navigation [34]. Such an approach provides that the tracked object will not move too far during the time of disturbance. Due to this fact the helicopter control system [31] will manage to return to the basic helicopter orientation which is taken up during a regular flight. It allows the camera head regulators to compensate change of the camera position and set the camera towards the object. In case of fast-moving objects it is indispensable to use information obtained from the image processing system. This image processing system informs us about the moving object direction. Conclusively, the essence of the proposed solution is to compute the object position only in such time intervals when the object is in the center of the image. Lead compensators PD used in close loops allow to considerably enhance the control quality for the assumed camera head model. For the specific camera head type it is necessary to find the mathematical model appropriate for this very type of the camera head. In this case the choice of the regulator depends on the previously obtained camera head mathematical model. All aforementioned examples illustrate that the developed solution operates correctly References [1] Davies, D., Palmer, P.L., Mirmehdi, M.: Detection and tracking of very small low contrast objects. In: Proceedings of the 9th British Machine Vision Conference (September 1998) [2] Zhang, S., Karim, M.A.: Automatic target tracking for video annotation. Op. Eng. 43, 1867–1873 (2004) [3] Irani, M., Peleg, S.: Improving resolution by image registration. CVGIP: Graph. Models and Image Process. 53, 231–239 (1991) [4] Chesnaud, C., Refegier, P., Boulet, V.: Statistical region snake-based segmentation adapted to different physical noise models. IEEE Trans. Patt. Anal. Mach. Intell. 21, 1145–1157 (1999) [5] Gordon, N., Ristic, B., Arulampalam, S.: Beyond the Kalman Filter: Particle Filters for Tracking Applications. Artech House, Boston (2004) [6] Sharp, C., Shakernia, O., Sastry, S.: A Vision System for Landing an Unmanned Aerial Vehicle. In: Proceedings of the 2001 IEEE International Conference on Robotics and Automation, vol. 2, pp. 1720–1727. IEEE, Los Alamitos (2001) [7] Casbeer, D., Li, S., Beard, R., Mehra, R., McLain, T.: Forest Fire Monitoring With Multiple Small UAVs, Porland, OR (April 2005) [8] Kuś, Z., Fraś, S.: Helicopter control algorithms from the set orientation to the set geographical Location. In: Nawrat, A., Simek, K., Świerniak, A. (eds.) Advanced Technologies for Intelligent Systems. SCI, vol. 440, pp. 3–14. Springer, Heidelberg (2013) [9] Nawrat, A.: Modelowanie i sterowanie bezzałogowych obiektów latających. Wydawnictwo Politechniki Śląskiej, Gliwice (2009) [10] Valavanis, K.P. (ed.): Advances In Unmanned Aerial Vehicles. Springer (2007)
Object Tracking for Rapid Camera Movements in 3D Space 75 [11] Castillo, P., Lozano, R., Dzul, A.E.: Modelling and Control of Mini-Flying Machines. Springer (2005) [12] Padfield, G.D.: Helicopter Flight Dynamics. Backwell Science Ltd. (1996) [13] Manerowski, J.: Identyfikacja modeli dynamiki ruchu sterowanych obiektów latających, WN ASKON, Warszawa (1999) [14] Kearney, J.K., Thompson, W.B.: Optical flow estimation: An error analysis of gradient-based methods with local optimization. IEEE Transactions on Pattern Analysis and Machine Intelligence 9, 229–243 (1987) [15] Anandan, P.: A computational framework and an algorithm for the measurement of visual motion. International Journal of Computer Vision 2, 283–310 (1989) [16] Barman, H., Haglund, L., Knutsson, H., Granlund, G.: Estimation of velocity, acceleration, and disparity in time sequences. In: Proc. IEEE Workshop on Visual Motion, Princeton, NJ, pp. 44–51 (1991) [17] Bascle, B., Bouthemy, E., Deriche, N., Meyer, E.: Tracking complex primitives in an image sequence. In: Proc. 12th International Conference on Pattern Recognition, Jerusalem, pp. 426–431 (1994) [18] Butt, E.J., Yen, C., Xu, X.: Local correlation measures for motion analysis: A comparative study. In: Pattern Recognition and Image Processing Conference, Las Vegas, pp. 269–274 (1982) [19] Butt, E.J., Bergen, J.R., Hingorani, R., Kolczynski, R., Lee, W.A., Leung, A., Lubin, J., Shvayster, H.: Object tracking with a moving camera. In: Proc. IEEE Workshop on Visual Motion, Irving, pp. 2–12 (1989) [20] Buxton, B.E., Buxton, H.: Computation of optical flow from the motion of edges features in image sequences. Image and Vision Computing 2(2), 59–75 (1984) [21] Campani, M., Verri, A.: Computing optical flow from an overconstrained system of linear algebraic equations. In: Proc. 3rd International Conference on Computer Vision, Osaka, pp. 22–26 (1990) [22] Campani, M., Verri, A.: Motion analysis from firstorder properties of optical flow. CVGIP: Image Understanding 56(1), 90–107 (1992) [23] Carlsson, S.: Information in the geometric structure of retinal flow field. In: Proc. 2nd International Conference on Computer Vision, pp. 629–633 (1988) [24] Gessing, R.: Control Fundamentals. Silesian University of Technology, Gliwice (2004) [25] Kuś, Z.: Object tracking in a picture during rapid camera movements [26] Babiarz, A., Jaskot, K., Koralewicz, P.: The control system for autonomous mobile platform. In: Nawrat, A., Simek, K., Świerniak, A. (eds.) Advanced Technologies for Intelligent Systems. SCI, vol. 440, pp. 15–28. Springer, Heidelberg (2013) [27] Babiarz, A., Jaskot, K.: The concept of collision-free path planning of UAV objects. In: Nawrat, A., Simek, K., Świerniak, A. (eds.) Advanced Technologies for Intelligent Systems. SCI, vol. 440, pp. 81–94. Springer, Heidelberg (2013) [28] Jaskot, K., Babiarz, A.: The inertial measurement unit for detection of position. Przegląd Elektrotechniczny 86, 323–333 (2010) [29] Grygiel, R., Pacholczyk, M.: Prototyping of control algorithms in matlab/Simulink. In: 14th World Multi-Conference on Systemics, Cybernetics and Informatis, WMSCI 2010, vol. 2, pp. 141–145 (2010) [30] Skorkowski, A., Topor-Kaminski, T.: Analysis of EGNOS-augmented receiver positioning accuracy. Acta Physica Polonica A 122(5), 821–824 (2012) [31] Daniec, K., Jedrasiak, K., Koteras, R., Nawrat, A.: Embedded micro inertial navigation system. Applied Mechanics and Materials 249-250, 1234–1246 (2013)
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Studies in Computational Intelligen
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Aleksander Nawrat · Zygmunt Kuś E
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“In God We Trust, All others we o
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VIII Preface valuable information i
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Contents Part I: Design of Object D
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Contents XIII Technology Developmen
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XVI List of Contributors Adam Czorn
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XVIII List of Contributors Henryk M
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XX List of Contributors Józef Wron
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2 Design of Object Detection, Recog
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4 A. Babiarz et al. 1 Introduction
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6 A. Babiarz et al. The description
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8 A. Babiarz et al. a) b) Fig. 5. T
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10 A. Babiarz et al. o o o “micvo
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12 A. Babiarz et al. a) b) Fig. 7.
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14 A. Babiarz et al. • The camera
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16 A. Babiarz et al. the camera ser
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18 A. Babiarz et al. a) b) Fig. 11.
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Part III Design of Vision Based Con
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Vision System for Group of Mobile R
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178 D. Bereska et al. The aim of th
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180 D. Bereska et al. 3 Control Alg
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182 D. Bereska et al. Fig. 5. Schem
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184 D. Bereska et al. 4.1 Mechanica
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186 D. Bereska et al. 4.1.3 Open-Lo
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188 D. Bereska et al. Fig. 16. Comp
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Probabilistic Approach to Planning
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206 Practical Applications of Class
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208 M. Mellado and K. Skrzypczyk an
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Prototyping the Autonomous Flight A
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Feature Extraction and HMM-Based Cl
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248 K. Daniec et al. In this articl
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250 K. Daniec et al. Fig. 2. Applic
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252 K. Daniec et al. by the ability
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254 K. Daniec et al. The idea of us
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284 A. Nawrat et al. Table 1. Compa
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286 A. Nawrat et al. P3 P3 P3 71101
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288 A. Nawrat et al. S, VA 4,510 4,
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Technology Development of Military
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344 Conclusions Control algorithms
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[Studies in Computational Intelligence 481] Artur Babiarz, Robert Bieda, Karol Jędrasiak, Aleksander Nawrat (auth.), Aleksander Nawrat, Zygmunt Kuś (eds.) - Vision Based Systemsfor UAV Applications (2013, Sprin

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