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Intelligent Service Robotics

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01-03-2021 | Original Research Paper

Flocks formation model for self-interested UAVs

Authors: Rina Azoulay, Shulamit Reches

Published in: Intelligent Service Robotics | Issue 2/2021

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Abstract

In recent years, unmanned aerial vehicles (UAVs) have been used in a wide range of domains. As the number of UAV flights increases, central flight areas may become overcrowded. This may cause delays in UAV traffic or gridlock on UAV routes. To address this challenge, we propose a flocking protocol that enables individual UAVs to optimize their flight preferences, while receiving the benefits of traveling in a group. Flocking can reduce overcrowding, and as a result, UAVs will be able to travel on less congested routes and have fewer encounters with other UAVs, thus reducing flight time and conserving energy. The protocol allows each UAV to create a flock or join an existing flock for all or part of its journey. We perform a simulation of UAV flights in an urban area and compare the average flight time of the UAVs based on various flight situations (e.g., different routes and participation in groups of UAVs). The simulation results demonstrate that the use of the flocking protocol significantly reduced the average flight time, and the flight saving rate increased with an increase in the UAV mean number. A similar effect is also observed in situations where each UAV and flock formed a dynamic A*-based path in advance to avoid collisions.

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Another possibility may be the union of two flocks listed on the blackboard, which may decide to move together on a particular route. In this case, the estimated departure time, estimated arrival time, and common route will be decided together by the flock managers and agreed upon by all the participating flocks. However, the detailed union protocol is beyond the scope of the current study .

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Valavanis KP, Vachtsevanos GJ (eds) (2015) Handbook of unmanned aerial vehicles. Springer, Berlin

Yang L, Qi J, Song D, Xiao J, Han J, Xia Y (2016) Survey of robot 3D path planning algorithms. J Control Sci Eng 2016:1–22MathSciNetMATH

Wang X, Yadav V, Balakrishnan SN (2007) Cooperative UAV formation flying with obstacle/collision avoidance. IEEE Trans Control Syst Technol 15(4):672–679CrossRef

McInnes CR (2003) Velocity field path-planning for single and multiple unmanned aerial vehicles. Aeronaut J 107(1073):419–426CrossRef

Bemporad A, Rocchi C (2011) decentralized linear time-varying model predictive control of a formation of unmanned aerial vehicles. In: 50th IEEE conference on decision and control and european control conference

Sundar K, Rathinam S (2016) Algorithms for heterogeneous, multiple depot, multiple unmanned vehicle path planning problems. Journal of Intelligent Robot Systemswith a special section on Unmanned Systems, J Intell Robot Syst

Yadav V, Wang X, Balakrishnan SN (2006) Neural network approach for obstacle avoidance in 3-d environments for UAVs. In: Proceedings of the (2006) American control conference. Minneapolis, Minnesota, USA

Owen M, Beard RW, McLain TW (2015) Implementing Dubins airplane paths on fixed-wing UAVs. In: Valavanis K, Vachtsevanos G (eds) Handbook of unmanned aerial vehicles. Springer, Berlin

Chen Y, Yu J, Su X, Luo G (2015) Path planning for multi-UAV formation. J Intell Robot Syst 77:229–246CrossRef

10.

Edwards DB, Bean TA., Odell DL, Anderson MJ (2004) A leader–follower algorithm for multiple AUV formations. In: IEEE/OES autonomous underwater vehicles

11.

Gao XZ, Hou ZX, Zhu XF, Zhang JT, Chen XQ (2013) The shortest path planning for manoeuvres of UAV. Acta Polytech Hung 10(1):221–239

12.

Ingersoll B, Ingersoll K, DeFranco P, Ning A (2016) UAV path-planning using bezier curves and a receding horizon approach. In: AIAA modeling and simulation technologies conference

13.

Qie H, Shi D, Shen T, Xu X, Li Y, Wang L (2019) Joint optimization of multi-UAV target assignment and path planning based on multi-agent reinforcement learning. In: IEEE access 7

14.

Wu Z, Li J, Zuo J, Li S (2018) Path planning of UAVs based on collision probability and Kalman filter. IEEE Access 6:34237–34245CrossRef

15.

Daifeng Z, Haibin D (2018) Social-class pigeon-inspired optimization and time stamp segmentation for multi-UAV cooperative path planning. Neurocomputing 313:229–246CrossRef

16.

Cekmez U, Ozsiginan M, Sahingoz OK (2018) Multi-UAV path planning with multi colony ant optimization. In: Abraham A, Muhuri P, Muda A, Gandhi N (eds) Intelligent systems design and applications. ISDA 2017. Advances in intelligent systems and computing, vol 736. Springer

17.

Hosak DG (2010) Optimal geometrical path in 3D with curvature constraint. In: Proceedings of the IEEE/RSJ international conference on intelligent robots and systems (IROS), pp 113–118, Taipei

18.

Seo J, Kim Y, Kim S, Tsourdos A (2017) Collision avoidance strategies for unmanned aerial vehicles in formation flight. IEEE Trans Aerosp Electron Syst 53(6):2718–2734CrossRef

19.

Azoulay R, Reches S (2019) UAV flocks forming for crowded flight environments. In: ICAART

20.

Hart P, Nilsson N, Raphael B (1968) A formal basis for the heuristic determination of minimum cost paths. IEEE Trans Syst Sci Cybern 4:100–107CrossRef

21.

Zeng W, Church RL (2009) Finding shortest paths on real road networks: the case for A*. Int J Geogr Inf Sci 23(4):531–543CrossRef

22.

Le AV, Prabakaran V, Sivanantham V, Mohan RE (2018) Modified a-star algorithm for efficient coverage path planning in tetris inspired self-reconfigurable robot with integrated laser sensor. Sensors 18:2585CrossRef

23.

Singh Y, Sharma S, Sutton R, Hatton D, Khan A (2018) A constrained A* approach towards optimal path planning for an unmanned surface vehicle in a maritime environment containing dynamic obstacles and ocean currents. Ocean Eng 169:187–201CrossRef

24.

Canny J, Reif J (1987) New lower bound techniques for robot motion planning problems. In: Proceedings of the symposium on the foundations of computer science

25.

Mitchell JSB, Sharir M (2004) New results on shortest paths in three dimensions. In: Proceedings of the ACM twentieth annual symposium on computational geometry, Brooklyn, New York, USA, pp 124–133

26.

Garcia M, Viguria A, Ollero A (2012) Dynamic graph-search algorithm for global path planning in presence of hazardous. J Int Robot Syst 69:285–295

27.

Zhong L, Xiao-Guang G, Xiao-Wei F (2015) Coalition formation for multiple heterogeneous UAVs in unknown environment. In: Fifth international conference on instrumentation and measurement, computer, communication and control (IMCCC), Qinhuangdao, pp 1222–1227

28.

Kuriki Y, Namerikawa T (2015) formation control with collision avoidance for a multi-UAV system using decentralized MPC and consensus-based control. SICE J Control Meas Syst Integr 8(4):285–294CrossRef

29.

Park S, Kim K, Kim H (2018) Formation control algorithm of multi-UAV-based network infrastructure. Appl Sci 8:1740CrossRef

30.

Kuriki Y, Namerikawa T (2014) Consensus-based cooperative formation control with collision avoidance for a multi-UAV system. In: American control conference, pp 2077–2082

31.

Danilechenko K (2016) Distributed cluster formation and management for maritime network. M.Sc. thesis, Beer Sheva University

32.

McCord C, Queralta JP, Gia TN, Westerlund T (2019) distributed progressive formation control for multi-agent systems: 2D and 3D deployment of UAVs in ROS/Gazebo with RotorS. In: European conference on mobile robots (ECMR), Prague, Czech Republic, pp 1–6

33.

Li X, Zhu D, Qian Y (2014) A survey on formation control algorithms for multi-AUV system. Special issue on autonomous underwater robots. Unmanned Syst 2(4):351–359CrossRef

34.

Mercado, DA, Castro1 R, Lozano R (2013) Quadrotors flight formation control using a leader–follower approach. In: European control conference (ECC)

35.

Ullaha Z (2020) A survey on hybrid, energy efficient and distributed (HEED) based energy efficient clustering protocols for wireless sensor networks. Wirel Pers Commun 112:2685–2713CrossRef

36.

Younis O, Fahmy S (2004) HEED: a hybrid, energy-efficient, distributed clustering approach for ad hoc sensor networks. IEEE Trans Mob Comput 3(4):366–379. https://doi.org/10.1109/TMC.2004.41CrossRef

37.

Beaver LE, Malikopoulos AA (2020) An overview on optimal flocking. arXiv:2009.14279

38.

Kraus S, Shehory O, Taase G (2004) The advantages of compromising in coalition formation with incomplete information. In: AAMAS

39.

Shehory O, Kraus S, Yadgar O (1999) Emergent cooperative goal-satisfaction in large-scale automated-agent systems. Artif Intell 110(1):1–55MATHCrossRef

40.

Sklab Y, Aknine S, Shehory O, Tari A (2020) Coalition formation with dynamically changing externalities. Eng Appl Artif Intell 91:103577CrossRef

41.

Ismail A, Bagula BA, Tuyishimire E (2018) Internet-of-Things in motion: a UAV coalition model for remote sensing in smart cities. Sensors 18(7):2184CrossRef

42.

Fu X, Zhang J, Zhang L et al (2019) Coalition formation among unmanned aerial vehicles for uncertain task allocation. Wireless Netw 25:367–377CrossRef

43.

Sujit PB, George JM, Beard RW (2008) Multiple UAV coalition formation. In: 2008 American control conference. Seattle, WA, pp 2010–2015

44.

Bardhan R, Ghose D (2013) Resource allocation and coalition formation for UAVs: a cooperative game approach. In: IEEE international conference on control applications (CCA), Hyderabad, pp 1200–1205

45.

George JM, Pinto J, Sujit PB, Sousa JB (2010) Multiple UAV coalition formation strategies. In: AAMAS

46.

Chen J, Li LR (2005) Path planning protocol for collaborative multi-robot systems. In: Proceedings IEEE international symposium on computational intelligence in robotics and automation

47.

Sinay M, Agmon N, Maksimov O, Levy G, Bitan M, Kraus S (2018) UAV/UGV search and capture of goal-oriented uncertain targets. In: IEEE/RSJ international conference on intelligent robots and systems (IROS), pp 8505–8512

48.

Yang Y, Polycarpou MM, Minai AA (2007) Multi-UAV cooperative search using an opportunistic learning method. J Dyn Syst Meas Control 129(5):716–728CrossRef

49.

Passino K, Polycarpou M, Jacques D, Pachter M, Liu Y, Yang Y, Flint M, Baum M (2002) Cooperative control for autonomous air vehicles. In: Murphey R, Pardalos PM (eds) Cooperative control and optimization. Applied optimization, vol 66. Springer, Berlin

50.

Bayındır L (2016) A review of swarm robotics tasks. Neurocomputing 172:292–321CrossRef

51.

Brutschy A, Pini G, Pinciroli C, Birattari M, Dorigo M (2014) Self-organized task allocation to sequentially interdependent tasks in swarm robotics. Auton Agents Multi-Agent Syst 28(1):101–125CrossRef

52.

Cianci CM, Raemy X, Pugh J, Martinoli A (2007) Communication in a swarm of miniature robots: the e-puck as an educational tool for swarm robotics. In: Sahin E, Spears WM, Winfield AFT (eds) Swarm robotics. SR (2006) Lecture notes in computer science, vol 4433. Springer, Berlin

53.

Sahin E, Winfield A (2008) Special issue on swarm robotics. Swarm Intell 2:69–72CrossRef

54.

Douchan Y, Kaminka GA (2019) Swarms can be rational. In: Proceedings of the 18th international conference on autonomous agents and multiagent systems (AAMAS 2019)

55.

Altmann A, Niendorf M, Bednar M, Reichel R (2014) Improved 3D interpolation-based path planning for a fixed-wing unmanned aircraft. J Intell Robot Syst 76:185–197CrossRef

56.

Duan H, Li P (2012) Path planning of unmanned aerial vehicle based on improved gravitational search algorithm. Sci China Technol Sci 55(10):2712–2719CrossRef

57.

Roberge V, Tarbouchi M, Labonte G (2013) Comparison of parallel genetic algorithm and particle swarm optimization for real-time UAV path planning. IEEE Trans Ind Inform 9(1):132–141CrossRef

58.

Duan H, Li P (2014) Bio-inspired computation in unmanned aerial vehicles. Springer, Berlin, pp 99–142CrossRef

59.

Gebhardt C (2016) Efficient transport system scheduling based on maximum flow algorithms. M.Sc. thesis, Institut für Informatik Lehrstuhl für Programmierung und Softwaretechnik, Ludwig-Maximilians-Universitat, Muenchen

60.

Brown A, Rogers J (2016) A sampling-based probabilistic path planner for multirotor air vehicles in cluttered environments. Proc Inst Mech Eng Part G J Aerosp Eng 231(1):143–162CrossRef

61.

Temizer S, Kochenderfer M, Kaelbling L, Lozano-Perez T, Kuchar J (2010) Collision avoidance for unmanned aircraft using Markov decision processes. In: AIAA guidance, navigation, and control conference, guidance, navigation, and control and co-located conferences

62.

Ragi S, Chong EKP (2013) UAV path planning in a dynamic environment via partially observable Markov decision process. IEEE Trans Aerosp Electron Syst 49(4):2397–2412CrossRef

63.

Vikranth Dabbiru R, Siddhabathula K (2016) Autonomous air traffic control–collision avoidance for UAVs using MDP. Int J Comput Sci Inf Technol Secur 6(1):447–454

64.

Nash, A, Daniel, K, Koenig, S, Felner, A (2007) Theta*: any-angle path planning on grids. In: Proceedings of the AAAI conference on artificial intelligence

65.

Nash A, Koenig S, Tovey, C (2010) Lazy theta*: any-angle path planning and path length analysis in 3D. In: Proceedings of the twenty-fourth AAAI conference on artificial intelligence (AAAI’10), pp 147–154

66.

Ferrera E, Alcántara H, Capitán J, Castaño AR, Marrón PJ, Aníbal Ollero A (2018) Decentralized 3D collision avoidance for multiple UAVs in outdoor environments. Sensors (Basel) 18(12):4101CrossRef

67.

Stiene S, Hertzberg J (2009) Virtual range scan for avoiding 3D obstacles using 2D tools. In: International conference on advanced robotics, Munich, 2009, pp 1–6

68.

Cakir M (2015) 2D path planning of UAVs with genetic algorithm in a constrained environment, In: 6th international conference on modeling, simulation, and applied optimization (ICMSAO), Istanbul, 2015, pp 1–5

69.

Rana T, Shankar A, Sultan MK, Patan R, Balusamy B (2019) An intelligent approach for UAV and drone privacy security using blockchain methodology. In: 9th international conference on cloud computing, data science and engineering (confluence), Noida, India, 2019, pp 162–167

70.

Chen CL, Deng YY, Weng W, Chen CH, Chiu YJ, Wu CM (2020) A traceable and privacy-preserving authentication for UAV communication control system. Electronics 9(1):62CrossRef

71.

Lagkas T, Argyriou V, Bibi S, Sarigiannidis P (2018) UAV IoT framework views and challenges: towards protecting drones as “things”. Sensors 18(11):4015CrossRef

72.

Arafat MY, Moh S (2018) A survey on cluster-based routing protocols for unmanned aerial vehicle networks. IEEE Access 7:498–516CrossRef

73.

Wang G, Lee B-S, Ahn JY, Cho G (2018) A UAV-aided cluster head election framework and applying such to security-driven cluster head election schemes: a survey. Secur Commun Netw 2018:6475927. https://doi.org/10.1155/2018/6475927

74.

Ahmad M, Hameed A, Ikram AA, Wahid I (2019) State-of-the-art clustering schemes in mobile ad hoc networks: objectives, challenges, and future directions. IEEE Access 7:17067–17081CrossRef

75.

Koushik AM, Hu F, Kumar S (2019) Deep Q-learning-based node positioning for throughput-optimal communications in dynamic UAV swarm network. IEEE Trans Cognit Commun Netw 5(3):554–566CrossRef

76.

Klaine PV, Nadas JPB, Souza RD et al (2018) Distributed drone base station positioning for emergency cellular networks using reinforcement learning. Cognit Comput 10:790–804CrossRef

77.

Medeiros FLL, da Silva JDS (2010) A Dijkstra algorithm for fixed-wing UAV motion planning based on terrain elevation. In: Advances in artificial intelligence—SBIA 2010. Springer, Berlin, pp 213–222

78.

Tseng FH, Liang TT, Lee CH, Der Chou L, Chao HC (2014) A star search algorithm for civil UAV path planning with 3G communication. In: Tenth international conference on intelligent information hiding and multimedia signal processing

79.

Liao T (2012) UAV collision avoidance using A* algorithm. M.Sc. thesis, Auburn, Alabama

Title: Flocks formation model for self-interested UAVs
Authors: Rina Azoulay
Shulamit Reches
Publication date: 01-03-2021
Publisher: Springer Berlin Heidelberg
Published in: Intelligent Service Robotics / Issue 2/2021
Print ISSN: 1861-2776
Electronic ISSN: 1861-2784
DOI: https://doi.org/10.1007/s11370-021-00354-x

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