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Cooperative Heterogeneous Multi-Robot Systems: A Survey

Authors:

Edward W. TunstelAuthors Info & Claims

ACM Computing Surveys (CSUR), Volume 52, Issue 2

Article No.: 29, Pages 1 - 31

https://doi.org/10.1145/3303848

Published: 09 April 2019 Publication History

Abstract

The emergence of the Internet of things and the widespread deployment of diverse computing systems have led to the formation of heterogeneous multi-agent systems (MAS) to complete a variety of tasks. Motivated to highlight the state of the art on existing MAS while identifying their limitations, remaining challenges, and possible future directions, we survey recent contributions to the field. We focus on robot agents and emphasize the challenges of MAS sub-fields including task decomposition, coalition formation, task allocation, perception, and multi-agent planning and control. While some components have seen more advancements than others, more research is required before effective autonomous MAS can be deployed in real smart city settings that are less restrictive than the assumed validation environments of MAS. Specifically, more autonomous end-to-end solutions need to be experimentally tested and developed while incorporating natural language ontology and dictionaries to automate complex task decomposition and leveraging big data advancements to improve perception algorithms for robotics.

References

[1]

Sameera Abar, Georgios K. Theodoropoulos, Pierre Lemarinier, and Gregory M. P. O’Hare. 2017. Agent based modelling and simulation tools: A review of the state-of-art software. Comput. Sci. Rev. 24 (May 2017), 13--33.

[2]

Ossama Abdel-Hamid, Abdel-rahman Mohamed, Hui Jiang, Li Deng, Gerald Penn, and Dong Yu. 2014. Convolutional neural networks for speech recognition. IEEE/ACM Trans. Aud. Speech Lang. Process. 22, 10 (2014), 1533--1545.

Digital Library

[3]

Tamer Abukhalil, Madhav Patil, Sarosh Patel, and Tarek Sobh. 2016. Coordinating a heterogeneous robot swarm using robot utility-based task assignment (RUTA). In Proceedings of the IEEE 14th International Workshop on Advanced Motion Control. 57--62.

[4]

Julie A. Adams et al. 2011. Coalition formation for task allocation: Theory and algorithms. Auton. Agents Multi-Agent Syst. 22, 2 (2011), 225--248.

Digital Library

[5]

Manoj Agarwal, Nitin Agrawal, Shikhar Sharma, Lovekesh Vig, and Naveen Kumar. 2015. Parallel multi-objective multi-robot coalition formation. Expert Syst. Applicat. 42, 21 (2015), 7797--7811.

Digital Library

[6]

Aamir Ahmad and Pedro Lima. 2013. Multi-robot cooperative spherical-object tracking in 3D space based on particle filters. Robot. Auton. Syst. 61, 10 (2013), 1084--1093.

Digital Library

[7]

Aamir Ahmad, Gian Diego Tipaldi, Pedro Lima, and Wolfram Burgard. 2013. Cooperative robot localization and target tracking based on least squares minimization. In Proceedings of the 2013 IEEE International Conference on Robotics and Automation (ICRA’13). IEEE, 5696--5701.

[8]

Filipp Akopyan, Jun Sawada, Andrew Cassidy, Rodrigo Alvarez-Icaza, John Arthur, Paul Merolla, Nabil Imam, Yutaka Nakamura, Pallab Datta, Gi-Joon Nam, et al. 2015. Truenorth: Design and tool flow of a 65 mw 1 million neuron programmable neurosynaptic chip. IEEE Trans. Comput.-Aid. Des. Integr. Circ. Syst. 34, 10 (2015), 1537--1557.

Digital Library

[9]

Christopher Amato, Girish Chowdhary, Alborz Geramifard, N. Kemal Ure, and Mykel J. Kochenderfer. 2013. Decentralized control of partially observable Markov decision processes. In Proceedings of the IEEE 52nd Annual Conference on Decision and Control. 2398--2405.

[10]

Christopher Amato, Frans A. Oliehoek, and Eric Shyu. 2013. Scalable bayesian reinforcement learning for multiagent POMDPs. In Proceedings of the 1st Multidisciplinary Conference on Reinforcement Learning and Decision Making.

[11]

Ofra Amir, Barbara J. Grosz, Edith Law, and Roni Stern. 2013. Collaborative health care plan support. In Proceedings of the International Conference on Autonomous Agents and Multi-agent Systems. International Foundation for Autonomous Agents 8 Multiagent Systems, 793--796.

Digital Library

[12]

Ofra Amir, Barbara J. Grosz, and Roni Stern. 2014. To share or not to share? The single agent in a team decision problem. In Proceedings of the 28th AAAI Conf. Artificial Intelligence (2014), 3092--3093.

Digital Library

[13]

Tamio Arai, Enrico Pagello, and Lynne E. Parker. 2002. Editorial: Advances in multi-robot systems. IEEE Trans. Robot. Autom. 18, 5 (2002), 655--661.

[14]

Nordmann Arne, Hochgeschwender Nico, Wigand Dennis, and Wrede Sebastian. 2016. A survey on domain-specific modeling and languages in robotics. J. Softw. Eng. Robot. 7, 1 (2016), 75--99.

[15]

Omur Arslan, Dan P. Guralnik, and Daniel E. Koditschek. 2016. Coordinated robot navigation via hierarchical clustering. IEEE Trans. Robot. 32, 2 (2016), 352--371.

Digital Library

[16]

Nikolay Atanasov, Jerome Le Ny, Kostas Daniilidis, and George J. Pappas. 2015. Decentralized active information acquisition: Theory and application to multi-robot SLAM. In Proceedings of the IEEE International Conference on Robotics and Automation. 4775--4782.

[17]

José Baca, Prithvi Pagala, Claudio Rossi, and Manuel Ferre. 2015. Modular robot systems towards the execution of cooperative tasks in large facilities. Robot. Auton. Syst. 66 (2015), 159--174.

Digital Library

[18]

Tim Bailey and Hugh Durrant-Whyte. 2006. Simultaneous localization and mapping (SLAM): Part II. IEEE Robot. Autom. Mag. 13, 3 (2006), 108--117.

[19]

Jan Carlo Barca and Y. Ahmet Sekercioglu. 2013. Swarm robotics reviewed. Robotica 31, 3 (2013), 345--359.

[20]

Samuel Barrett and Peter Stone. 2015. Cooperating with unknown teammates in complex domains: A robot soccer case study of ad hoc teamwork. In Proceedings of the AAAI Conference on Artificial Intelligence (AAAI’15). 2010--2016.

Digital Library

[21]

Levent Bayındır. 2016. A review of swarm robotics tasks. Neurocomputing 172 (2016), 292--321.

Digital Library

[22]

Michael Beetz, Lorenz Mösenlechner, and Moritz Tenorth. 2010. CRAM: A cognitive robot abstract machine for everyday manipulation in human environments. In Proceedings of the 2010 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS’10). IEEE, 1012--1017.

[23]

Patrick Benavidez, Mohan Kumar, Sos Agaian, and Mo Jamshidi. 2015. Design of a home multi-robot system for the elderly and disabled. In Proceedings of the 10th Annual Systems of Engineering Conference. IEEE, 392--397.

[24]

Gerardo Beni and Jing Wang. 1993. Swarm intelligence in cellular robotic systems. In Robots and Biological Systems: Towards a New Bionics? Springer, 703--712.

[25]

Ahmed Benzerrouk, Lounis Adouane, and Philippe Martinet. 2014. Stable navigation in formation for a multi-robot system based on a constrained virtual structure. Robot. Auton. Syst. 62, 12 (2014), 1806--1815.

Digital Library

[26]

Daniel S. Bernstein, Christopher Amato, Eric A. Hansen, and Shlomo Zilberstein. 2009. Policy iteration for decentralized control of Markov decision processes. J. Artif. Intell. Res. 34, 1 (2009), 89.

Digital Library

[27]

A. H. Bond and L. Gasser. 1988. Readings in Distributed Artificial Intelligence. Morgan Kaufmann.

Digital Library

[28]

Sylvia C. Botelho and Rachid Alami. 1999. M+: A scheme for multi-robot cooperation through negotiated task allocation and achievement. In Proceedings of the IEEE International Conference on Robotics and Automation, Vol. 2. 1234--1239.

[29]

Manuele Brambilla, Eliseo Ferrante, Mauro Birattari, and Marco Dorigo. 2013. Swarm robotics: A review from the swarm engineering perspective. Swarm Intell. 7, 1 (2013), 1--41.

[30]

Luis Búrdalo, Andrés Terrasa, Vicente Julián, and Ana García-Fornes. 2018. The information flow problem in multi-agent systems. Eng. Appl. Artif. Intell. 70 (April 2018), 130--141.

[31]

Zack Butler and Jacob Hays. 2015. Task allocation for reconfigurable teams. Robot. Auton. Syst. 68 (June 2015), 59--71.

Digital Library

[32]

Philippe Caloud, Wonyun Choi, Jean-Claude Latombe, Claude Le Pape, and Mark Yim. 1990. Indoor automation with many mobile robots. In Proceedings of the IEEE International Workshop on Intelligent Robots and Systems: Towards a New Frontier of Applications. 67--72.

[33]

Adam Campbell and Annie S. Wu. 2011. Multi-agent role allocation: Issues, approaches, and multiple perspectives. Auton. Agents Multi-agent Syst. 22, 2 (2011), 317--355.

Digital Library

[34]

Georgios Chalkiadakis and Craig Boutilier. 2012. Sequentially optimal repeated coalition formation under uncertainty. Auton. Agents Multi-Agent Syst. 24, 3 (2012), 441--484.

Digital Library

[35]

Praneel Chand and Dale A. Carnegie. 2013. Mapping and exploration in a hierarchical heterogeneous multi-robot system using limited capability robots. Robot. Auton. Syst. 61, 6 (2013), 565--579.

[36]

Jianping Chen, Yimin Yang, and Liang Wei. 2010. Research on the approach of task decomposition in soccer robot system. In Proceedings of the IEEE International Conference on Digital Manufacturing and Automation, Vol. 2. 284--289.

Digital Library

[37]

Chen Tun Chou, Jiun-Yi Li, Ming-Fang Chang, and Li Chen Fu. 2011. Multi-robot cooperation based human tracking system using laser range finder. In Proceedings of the International Conference on Robotics and Automation. IEEE, 532--537.

[38]

B. B. Choudhury and B. B. Biswal. 2008. Task allocation methodologies for multi-robot systems. IEEE Sponsored Conf. Computational Intelligence, Control 8 Computer Vision in Robotics 8 Automation (2008), 99--106.

[39]

CNBC. 2016. An Internet of Things That Will number Ten Billions. Retrieved from http://www.cnbc.com/2016/02/01/an-internet-of-things-that-will-number-ten-billions.html.

[40]

Luis C. Cobo, Charles L. Isbell Jr, and Andrea L. Thomaz. 2012. Automatic task decomposition and state abstraction from demonstration. In Proceedings of the 11th International Conference on Autonomous Agents and Multiagent Systems, Vol. 1. 483--490.

Digital Library

[41]

Xuefeng Dai, Laihao Jiang, and Yan Zhao. 2016. Cooperative exploration based on supervisory control of multi-robot systems. Appl. Intell. 45, 1 (2016), 1--12.

Digital Library

[42]

Gautham P. Das, Thomas Martin McGinnity, and Sonya A. Coleman. 2014. Simultaneous allocations of multiple tightly-coupled multi-robot tasks to coalitions of heterogeneous robots. In Proceedings of the IEEE International Conference on Robotics and Biomimetics. 1198--1204.

[43]

Gautham P. Das, Thomas M. McGinnity, Sonya A. Coleman, and Laxmidhar Behera. 2015. A distributed task allocation algorithm for a multi-robot system in healthcare facilities. J. Intell. Robot. Syst. 80, 1 (2015), 33--58.

Digital Library

[44]

Prithviraj Dasgupta, José Baca, K. R. Guruprasad, Angélica Muñoz-Meléndez, and Janyl Jumadinova. 2015. The COMRADE system for multirobot autonomous landmine detection in postconflict regions. J. Robot. 2015 (2015), 17 pages.

[45]

Prithviraj Dasgupta and Ke Cheng. 2015. Dynamic multi-robot team reconfiguration using weighted voting games. J. Exp. Theoret. Artif. Intell. 28, 4 (2015), 1--22.

[46]

Prithviraj Dasgupta, Ke Cheng, and Bikramjit Banerjee. 2012. Adaptive multi-robot team reconfiguration using a policy-reuse reinforcement learning approach. In Advanced Agent Technology. Springer, 330--345.

Digital Library

[47]

Paul Davidsson, Stefan Johansson, and Mikael Svahnberg. 2005. Characterization and evaluation of multi-agent system architectural styles. In Software Engineering for Multi-Agent Systems IV. Springer, 179--188.

[48]

Elias De Coninck, Tim Verbelen, Bert Vankeirsbilck, Steven Bohez, Sam Leroux, and Pieter Simoens. 2015. Dianne: Distributed artificial neural networks for the internet of things. In Proceedings of the 2nd Workshop on Middleware for Context-Aware Applications in the IoT. ACM, 19--24.

Digital Library

[49]

Gabriel de O Ramos, Juan C. Burguillo Rial, and Ana L. C. Bazzan. 2013. Self-adapting coalition formation among electric vehicles in smart grids. In Proceedings of the IEEE International Conference on Self-Adaptive and Self-Organizing Systems. 11--20.

Digital Library

[50]

Coline Devin, Abhishek Gupta, Trevor Darrell, Pieter Abbeel, and Sergey Levine. 2017. Learning modular neural network policies for multi-task and multi-robot transfer. In Proceedings of the 2017 IEEE International Conference on Robotics and Automation (ICRA’17). IEEE, 2169--2176.

Digital Library

[51]

Nitin Kumar Dhiman, Dipti Deodhare, and Deepak Khemani. 2015. Where am I? creating spatial awareness in unmanned ground robots using SLAM: A survey. Sadhana 40, 5 (2015), 1385--1433.

[52]

Donato Di Paola, Annalisa Milella, Grazia Cicirelli, and Arcangelo Distante. 2010. An autonomous mobile robotic system for surveillance of indoor environments. Int. J. Adv. Robot. Syst. 7, 1 (2010), 8.

[53]

M. Bernardine Dias. 2004. Traderbots: A New Paradigm for Robust and Efficient Multirobot Coordination in Dynamic Environments. Ph.D. Dissertation. Carnegie Mellon University, Pittsburgh.

Digital Library

[54]

M. Bernardine Dias, Robert Zlot, Nidhi Kalra, and Anthony Stentz. 2006. Market-based multirobot coordination: A survey and analysis. Proc. IEEE 94, 7 (2006), 1257--1270.

[55]

Marco Dorigo, Dario Floreano, Luca M. Gambardella, Francesco Mondada, Stefano Nolfi, Tarek Baaboura, Mauro Birattari, Michael Bonani, Manuele Brambilla, Arne Brutschy, et al. 2013. Swarmanoid: A novel concept for the study of heterogeneous robotic swarms. IEEE Robot. Autom. Mag. 20, 4 (2013), 60--71.

[56]

Rajesh Doriya, Siddharth Mishra, and Swati Gupta. 2015. A brief survey and analysis of multi-robot communication and coordination. In Proceedings of the 2015 International Conference on Computing, Communication 8 Automation (ICCCA’15). IEEE, 1014--1021.

[57]

Fernando Dos Santos and Ana L. C. Bazzan. 2011. Towards efficient multiagent task allocation in the robocup rescue: A biologically-inspired approach. Auton. Agents Multi-Agent Syst. 22, 3 (2011), 465--486.

Digital Library

[58]

Haibin Duan and Peixin Qiao. 2014. Pigeon-inspired optimization: A new swarm intelligence optimizer for air robot path planning. Int. J. Intell. Comput. Cybernet. 7, 1 (2014), 24--37.

[59]

Francois Dufour and Tomas Prieto-Rumeau. 2013. Finite linear programming approximations of constrained discounted Markov decision processes. SIAM J. Contr. Optim. 51, 2 (2013), 1298--1324.

Digital Library

[60]

Hugh Durrant-Whyte and Tim Bailey. 2006. Simultaneous localization and mapping: Part I. IEEE Robot. Autom. Mag. 13, 2 (2006), 99--110.

[61]

Barış Eker and H. Levent Akın. 2013. Solving decentralized POMDP problems using genetic algorithms. Auton. Agents Multi-agent Syst. 27, 1 (2013), 161--196.

Digital Library

[62]

Murugappan Elango, Ganesan Kanagaraj, and S. G. Ponnambalam. 2013. Sandholm algorithm with K-means clustering approach for multi-robot task allocation. In Swarm, Evolutionary, and Memetic Computing. Springer, 14--22.

Digital Library

[63]

Pablo Escandell-Montero, José M. Martínez-Martínez, José D. Martín-Guerrero, Emilio Soria-Olivas, and Juan Gómez-Sanchis. 2014. Least-squares temporal difference learning based on an extreme learning machine. Neurocomputing 141 (Oct. 2014), 37--45.

[64]

Alessandro Farinelli, Giorgio Grisetti, Luca Iocchi, S. Lo Cascio, and Daniele Nardi. 2003. Design and evaluation of multi agent systems for rescue operations. In Proceedings of the IEEE International Conference on Intelligent Robots and Systems, Vol. 4. 3138--3143.

[65]

Jacques Ferber. 1999. Multi-agent Systems: An Introduction to Distributed Artificial Intelligence. Vol. 1. Addison-Wesley, Reading, MA.

Digital Library

[66]

Borja Fernandez-Gauna, Ismael Etxeberria-Agiriano, and Manuel Graña. 2015. Learning multirobot hose transportation and deployment by distributed round-robin q-learning. PLoS ONE 10, 7 (2015), e0127129.

[67]

Matthias Feurer, Aaron Klein, Katharina Eggensperger, Jost Springenberg, Manuel Blum, and Frank Hutter. 2015. Efficient and robust automated machine learning. In Advances in Neural Information Processing Systems. 2962--2970.

Digital Library

[68]

Jorge Fuentes-Pacheco, José Ruiz-Ascencio, and Juan Manuel Rendón-Mancha. 2015. Visual simultaneous localization and mapping: A survey. Artif. Intell. Rev. 43, 1 (2015), 55--81.

Digital Library

[69]

Cipriano Galindo, Juan-Antonio Fernández-Madrigal, Javier González, and Alessandro Saffiotti. 2008. Robot task planning using semantic maps. Robot. Auton. Syst. 56, 11 (2008), 955--966.

Digital Library

[70]

Andreas Geiger, Martin Lauer, and Raquel Urtasun. 2011. A generative model for 3d urban scene understanding from movable platforms. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition. 1945--1952.

Digital Library

[71]

Brian P. Gerkey and Maja J. Matari. 2002. Sold&excl;: Auction methods for multirobot coordination. IEEE Trans. Robot. Autom. 18, 5 (2002), 758--768.

[72]

Brian P. Gerkey and Maja J. Matarić. 2004. A formal analysis and taxonomy of task allocation in multi-robot systems. Int. J. Robot. Res. 23, 9 (2004), 939--954.

[73]

Piotr J. Gmytrasiewicz and Prashant Doshi. 2004. Interactive POMDPs: Properties and preliminary results. In Proceedings of the 3rd International Joint Conference on Autonomous Agents and Multiagent Systems, Vol. 3. IEEE, 1374--1375.

Digital Library

[74]

Randy Gomez, Tatsuya Kawahara, Keisuke Nakamura, and Kazuhiro Nakadai. 2012. Multi-party human-robot interaction with distant-talking speech recognition. In Proceedings of the 7th Annual ACM/IEEE International Conference on Human--Robot Interaction. 439--446.

Digital Library

[75]

Bruno Duarte Gouveia, David Portugal, Daniel C. Silva, and Lino Marques. 2015. Computation sharing in distributed robotic systems: A case study on SLAM. IEEE Trans. Autom. Sci. Eng. 12, 2 (2015), 410--422.

[76]

Jason Gregory, Jonathan Fink, Ethan Stump, Jeffrey Twigg, John Rogers, David Baran, Nicholas Fung, and Stuart Young. 2016. Application of multi-robot systems to disaster-relief scenarios with limited communication. In Field and Service Robotics. Springer, 639--653.

[77]

Luigi Alfredo Grieco, Alessandro Rizzo, Simona Colucci, Sabrina Sicari, Giuseppe Piro, Donato Di Paola, and Gennaro Boggia. 2014. IoT-aided robotics applications: Technological implications, target domains and open issues. Comput. Commun. 54 (2014), 32--47.

Digital Library

[78]

Tyler Gunn and John Anderson. 2013. Dynamic heterogeneous team formation for robotic urban search and rescue. Proc. Comput. Sci. 19 (2013), 22--31.

[79]

Ruiqi Guo. 2014. Scene Understanding with Complete Scenes and Structured Representations. Ph.D. Dissertation. University of Illinois at Urbana--Champaign.

[80]

Isabelle Guyon, Imad Chaabane, Hugo Jair Escalante, Sergio Escalera, Damir Jajetic, James Robert Lloyd, Núria Macià, Bisakha Ray, Lukasz Romaszko, Michèle Sebag, et al. 2016. A brief review of the chalearn automl challenge: Any-time any-dataset learning without human intervention. In Proceedings of the Workshop on Automatic Machine Learning. 21--30.

[81]

Song Han, Huizi Mao, and William J. Dally. 2015. Deep compression: Compressing deep neural networks with pruning, trained quantization and huffman coding. Int. Conf. Learning Representations (ICLR'16). 1--14.

[82]

Alexander Hans and Steffen Udluft. 2010. Ensembles of neural networks for robust reinforcement learning. In Proceedings of the 9th International Conference on Machine Learning and Applications. IEEE, 401--406.

Digital Library

[83]

Yihui He, Ji Lin, Zhijian Liu, Hanrui Wang, Li-Jia Li, and Song Han. 2018. Amc: Automl for model compression and acceleration on mobile devices. In Proceedings of the European Conference on Computer Vision (ECCV’18). 784--800.

Digital Library

[84]

Stefan Heinrich and Stefan Wermter. 2011. Towards robust speech recognition for human-robot interaction. In Proceedings of the IROS Workshop on Cognitive Neuroscience Robotics. 29--34.

[85]

E. G. Hernandez-Martinez, E. D. Ferreira-Vazquez, A. Lopez-Gonzalez, J. J. Flores-Godoy, G. Fernandez-Anaya, and P. Paniagua-Contro. 2016. Formation control of heterogeneous robots using distance and orientation. In Proceedings of the IEEE International Conference on Control Applications. 507--512.

[86]

Daylond J. Hooper, Gilbert L. Peterson, and Brett J. Borghetti. 2009. Dynamic coalition formation under uncertainty. In Proceedings of the IEEE/RSJ International Conference on Intelligent Robots and Systems. 4799--4804.

Digital Library

[87]

Andrew Howard, Lynne E. Parker, and Gaurav S. Sukhatme. 2006. Experiments with a large heterogeneous mobile robot team: Exploration, mapping, deployment and detection. Int. J. Robot. Res. 25, 5--6 (2006), 431--447.

Digital Library

[88]

Tao Hu, Stefano Messelodi, and Oswald Lanz. 2014. Dynamic task decomposition for probabilistic tracking in complex scenes. In Proceedings of the 22nd IEEE International Conference on Pattern Recognition. 4134--4139.

Digital Library

[89]

Ting-Hao Kenneth Huang, Walter S. Lasecki, Amos Azaria, and Jeffrey P. Bigham. 2016. “Is there anything else I can help you with?”: Challenges in deploying an on-demand crowd-powered conversational agent. In Proceedings of the 4th AAAI Conference on Human Computation and Crowdsourcing.

[90]

IBM. 2015. 1st Workshop on Cognitive Architectures. Retrieved from http://researcher.watson.ibm.com/researcher/view_group.php?id=5848.

[91]

Gökhan Ince, Kazuhiro Nakadai, Tobias Rodemann, Hiroshi Tsujino, and Jun-Ichi Imura. 2011. Whole body motion noise cancellation of a robot for improved automatic speech recognition. Adv. Robot. 25, 11--12 (2011), 1405--1426.

[92]

Pablo Iñigo-Blasco, Fernando Diaz-del Rio, Ma Carmen Romero-Ternero, Daniel Cagigas-Muñiz, and Saturnino Vicente-Diaz. 2012. Robotics software frameworks for multi-agent robotic systems development. Robot. Auton. Syst. 60, 6 (2012), 803--821.

Digital Library

[93]

Muhammad Irfan and Adil Farooq. 2016. Auction-based task allocation scheme for dynamic coalition formations in limited robotic swarms with heterogeneous capabilities. In Proceedings of the IEEE International Conference on Intelligent Systems Engineering. 210--215.

[94]

Xiao Jia and Max Q.-H. Meng. 2013. A survey and analysis of task allocation algorithms in multi-robot systems. In Proceedings of the IEEE International Conference on Robotics and Biomimetics. 2280--2285.

[95]

Hui Jiang. 2010. Discriminative training of HMMs for automatic speech recognition: A survey. Comput. Speech Lang. 24, 4 (2010), 589--608.

Digital Library

[96]

Jiong Jin, Jayavardhana Gubbi, Slaven Marusic, and Marimuthu Palaniswami. 2014. An information framework for creating a smart city through internet of things. IEEE IoT J. 1, 2 (2014), 112--121.

[97]

E. Gil Jones, Brett Browning, M. Bernardine Dias, Brenna Argall, Manuela Veloso, and Anthony Stentz. 2006. Dynamically formed heterogeneous robot teams performing tightly-coordinated tasks. In Proceedings of the IEEE International Conference on Robotics and Automation. 570--575.

[98]

K. Kakinuma, Makoto Ozaki, Masafumi Hashimoto, T. Yokoyama, and Kazuhiko Takahashi. 2011. Laser-based pedestrian tracking with multiple mobile robots using outdoor SLAM. In Proceedings of the IEEE International Conference on Robotics and Biomimetics. 998--1003.

[99]

Ben Kehoe, Sachin Patil, Pieter Abbeel, and Ken Goldberg. 2015. A survey of research on cloud robotics and automation. IEEE Trans. Autom. Sci. Eng. 12, 2 (2015), 398--409.

[100]

James Kennedy and Eberhart Russell C. 1995. Particle swarm optimization. In Proceedings of the International Conference on Neural Networks. IEEE Press, 1942--1948.

[101]

Jutta Kiener and Oskar Von Stryk. 2010. Towards cooperation of heterogeneous, autonomous robots: A case study of humanoid and wheeled robots. Robot. Auton. Syst. 58, 7 (2010), 921--929.

Digital Library

[102]

Hongkeun Kim, Hyungbo Shim, and Jin Heon Seo. 2011. Output consensus of heterogeneous uncertain linear multi-agent systems. IEEE Trans. Autom. Contr. 56, 1 (2011), 200--206.

[103]

In Su Kim, Hong Seok Choi, Kwang Moo Yi, Jin Young Choi, and Seong G. Kong. 2010. Intelligent visual surveillance survey. Int. J. Contr. Autom. Syst. 8, 5 (2010), 926--939.

[104]

Jonghoek Kim. 2016. Cooperative exploration and networking while preserving collision avoidance. IEEE Trans. Cybern. 47, 12 (2016), 4038--4048.

[105]

Min-Hyuk Kim, Hyeoncheol Baik, and Seokcheon Lee. 2015. Resource welfare based task allocation for UAV team with resource constraints. J. Intell. Robot. Syst. 77, 3--4 (2015), 611--627.

Digital Library

[106]

Alexander Kleiner and Dali Sun. 2007. Decentralized SLAM for pedestrians without direct communication. In Proceedings of the IEEE/RSJ International Conference on Intelligent Robots and Systems. 1461--1466.

[107]

Matthias Klusch and Andreas Gerber. 2002. Dynamic coalition formation among rational agents. IEEE Intell. Syst. 17, 3 (2002), 42--47.

Digital Library

[108]

Jens Kober and Jan Peters. 2012. Reinforcement learning in robotics: A survey. In Reinforcement Learning. Springer, 579--610.

[109]

G. Ayorkor Korsah, Anthony Stentz, and M. Bernardine Dias. 2013. A comprehensive taxonomy for multi-robot task allocation. Int. J. Robot. Res. 32, 12 (2013), 1495--1512.

Digital Library

[110]

Iuliia Kotseruba, Oscar J. Avella Gonzalez, and John K. Tsotsos. 2016. A review of 40 years of cognitive architecture research: Focus on perception, attention, learning and applications. arXiv preprint arXiv:1610.08602, 1--74.

[111]

Sarit Kraus. 2015. Intelligent agents for rehabilitation and care of disabled and chronic patients. In Proceedings of the AAAI Conference on Artificial Intelligence (AAAI’15). 4032--4036.

Digital Library

[112]

Sarit Kraus, Onn Shehory, and Gilad Taase. 2003. Coalition formation with uncertain heterogeneous information. In Proceedings of the 2nd International Joint Conference on Autonomous Agents and Multiagent Systems. ACM, 1--8.

Digital Library

[113]

Pradeep Kumar Krishnappa and B. R. Prasad Babu. 2015. Investigating open issues in swarm intelligence for mitigating security threats in MANET. Int. J. Elect. Comput. Eng. 5, 5 (2015).

[114]

Nicholas D. Lane, Sourav Bhattacharya, Petko Georgiev, Claudio Forlivesi, Lei Jiao, Lorena Qendro, and Fahim Kawsar. 2016. Deepx: A software accelerator for low-power deep learning inference on mobile devices. In Proceedings of the 15th International Conference on Information Processing in Sensor Networks. IEEE Press, 23.

Digital Library

[115]

Pat Langley, John E. Laird, and Seth Rogers. 2009. Cognitive architectures: Research issues and challenges. Cogn. Syst. Res. 10, 2 (2009), 141--160.

Digital Library

[116]

Charles Lesire, Guillaume Infantes, Thibault Gateau, and Magali Barbier. 2016. A distributed architecture for supervision of autonomous multi-robot missions. Auton. Robots 40, 7 (2016), 1343--1362.

Digital Library

[117]

Keith Y. K. Leung, Timothy D. Barfoot, and Hugh H. T. Liu. 2010. Decentralized cooperative simultaneous localization and mapping for dynamic and sparse robot networks. In Proceedings of the IEEE/RSJ International Conference on Intelligent Robots and Systems. 3554--3561.

[118]

Chi Li, Han Xiao, Keisuke Tateno, Federico Tombari, Nassir Navab, and Gregory D. Hager. 2016. Incremental scene understanding on dense SLAM. In Proceedings of the 2016 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS’16). IEEE, 574--581.

[119]

Jinyu Li, Li Deng, Yifan Gong, and Reinhold Haeb-Umbach. 2014. An overview of noise-robust automatic speech recognition. IEEE/ACM Trans. Aud. Speech Lang. Process. 22, 4 (2014), 745--777.

Digital Library

[120]

Xiong Li, Sheng Dang, Kunju Li, and Qiansheng Liu. 2010. Multi-agent-based battlefield reconnaissance simulation by novel task decomposition and allocation. In Proceedings of the 5th IEEE International Conference on Computer Science and Education. 1410--1414.

[121]

Zhiyong Li, Bo Xu, Lei Yang, Jun Chen, and Kenli Li. 2009. Quantum evolutionary algorithm for multi-robot coalition formation. In Proceedings of the 1st ACM/SIGEVO Summit on Genetic and Evolutionary Computation. 295--302.

Digital Library

[122]

Stephen Shaoyi Liao, Jia-Dong Zhang, Raymond Lau, and Tianying Wu. 2014. Coalition formation based on marginal contributions and the markov process. Decis. Supp. Syst. 57 (Jan. 2014), 355--363.

Digital Library

[123]

S. H. Liu, Yu Zhang, H. Y. Wu, and Jie Liu. 2010. Multi-robot task allocation based on swarm intelligence. J. Jilin Univ. 40, 1 (2010), 123--129.

[124]

Zheng Liu, Marcelo H. Ang Jr, and Winston Khoon Guan Seah. 2005. Reinforcement learning of cooperative behaviors for multi-robot tracking of multiple moving targets. In Proceedings of the IEEE/RSJ International Conference on Intelligent Robots and Systems. 1289--1294.

[125]

Z. Liu, W. Chen, J. Lu, H. Wang, and J. Wang. 2016. Formation control of mobile robots using distributed controller with sampled-data and communication delays. IEEE Trans. Contr. Syst. Technol. 24, 6 (2016), 2125--2132.

[126]

Zhong Liu, Xiao-guang Gao, and Xiao-wei Fu. 2016. Coalition formation for multiple heterogeneous UAVs cooperative search and prosecute with communication constraints. In Proceedings of the Chinese Control 8 Decision Conference. IEEE, 1727--1734.

[127]

D. F. Llorca, M. A. Sotelo, A. M. Hellín, A. Orellana, M. Gavilán, I. G. Daza, and A. G. Lorente. 2012. Stereo regions-of-interest selection for pedestrian protection: A survey. Transport. Res. C: Emerg. Technol. 25 (2012), 226--237.

[128]

Matt Luckcuck, Marie Farrell, Louise Dennis, Clare Dixon, and Michael Fisher. 2018. Formal specification and verification of autonomous robotic systems: A survey. Arxiv Preprint Arxiv:1807.00048 (2018).

[129]

Ewa Luger and Abigail Sellen. 2016. Like having a really bad PA: The gulf between user expectation and experience of conversational agents. In Proceedings of the 2016 CHI Conference on Human Factors in Computing Systems. ACM, 5286--5297.

Digital Library

[130]

Jarmo Lunden, Sanjeev R. Kulkarni, Visa Koivunen, and H. Vincent Poor. 2013. Multiagent reinforcement learning based spectrum sensing policies for cognitive radio networks. IEEE J. Sel. Topics Signal Process. 7, 5 (2013), 858--868.

[131]

Damian M. Lyons, Michael Arbib, et al. 1989. A formal model of computation for sensory-based robotics. IEEE Trans. Robot. Autom. 5, 3 (1989), 280--293.

[132]

Joel G. Manathara, P. B. Sujit, and Randal W. Beard. 2011. Multiple UAV coalitions for a search and prosecute mission. J. Intell. Robot. Syst. 62, 1 (2011), 125--158.

Digital Library

[133]

Neil Mathew, Stephen L. Smith, and Steven L. Waslander. 2015. Planning paths for package delivery in heterogeneous multirobot teams. IEEE Trans. Autom. Sci. Eng. 12, 4 (2015), 1298--1308.

[134]

Tim Matthews, Sarvapali Ramchurn, and Georgios Chalkiadakis. 2012. Competing with humans at fantasy football: Team formation in large partially-observable domains. In Proceedings of the 26th AAAI Conf. Artificial Intelligence (2012), 1394--1400.

Digital Library

[135]

Nikolaos Mavridis. 2015. A review of verbal and non-verbal human--robot interactive communication. Robot. Auton. Syst. 63 (2015), 22--35.

Digital Library

[136]

Kathryn Merrick. 2017. Value systems for developmental cognitive robotics: A survey. Cogn. Syst. Res. 41 (2017), 38--55.

Digital Library

[137]

Piotr Mirowski, Tin Kam Ho, Saehoon Yi, and Michael MacDonald. 2013. SignalSLAM: Simultaneous localization and mapping with mixed wifi, bluetooth, LTE and magnetic signals. In Proceedings of the International Conference on Indoor Positioning and Indoor Navigation. IEEE, 1--10.

[138]

Volodymyr Mnih, Adria Puigdomenech Badia, Mehdi Mirza, Alex Graves, Timothy P. Lillicrap, Tim Harley, David Silver, and Koray Kavukcuoglu. 2016. Asynchronous methods for deep reinforcement learning. Int. Conf. Machine Learning (2016), 1928--1937.

Digital Library

[139]

Fabio Morbidi, Christopher Ray, and Gian Luca Mariottini. 2011. Cooperative active target tracking for heterogeneous robots with application to gait monitoring. In Proceedings of the IEEE/RSJ International Conference on Intelligent Robots and Systems. IEEE, 3608--3613.

[140]

Davide Moroni, Maria Antonietta Pascali, Marco Reggiannini, and Ovidio Salvetti. 2013. Underwater scene understanding by optical and acoustic data integration. In Proceedings of the Meetings on Acoustics, Vol. 17. Acoustical Society of America.

[141]

Robin R. Murphy, Karen L. Dreger, Sean Newsome, Jesse Rodocker, Brian Slaughter, Richard Smith, Eric Steimle, Tetsuya Kimura, Kenichi Makabe, Kazuyuki Kon, et al. 2012. Marine heterogeneous multirobot systems at the great eastern japan tsunami recovery. J. Field Robot. 29, 5 (2012), 819--831.

Digital Library

[142]

Richard M. Murray. 2007. Recent research in cooperative control of multivehicle systems. J. Dynam. Syst. Meas. Contr. 129, 5 (2007), 571--583.

[143]

Sarat Chandra Nagavarapu, Leena Vachhani, and Arpita Sinha. 2015. Multi-robot graph exploration and map building with collision avoidance: A decentralized approach. J. Intell. Robot. Syst. (2015), 1--21.

[144]

Richard A. Newcombe, Shahram Izadi, Otmar Hilliges, David Molyneaux, David Kim, Andrew J. Davison, Pushmeet Kohi, Jamie Shotton, Steve Hodges, and Andrew Fitzgibbon. 2011. KinectFusion: Real-time dense surface mapping and tracking. In Proceedings of the International Symposium on Mixed and Augmented Reality. IEEE, 127--136.

Digital Library

[145]

Martin Ngobye, Wouter T. De Groot, and Theo P. Van Der Weide. 2010. Types and priorities of multi-agent system interactions. Interdisc. Descr. Complex Syst. 8, 1 (2010), 49--58.

[146]

Tejaswi Nimmagadda and Anima Anandkumar. 2015. Multi-object classification and unsupervised scene understanding using deep learning features and latent tree probabilistic models. Arxiv Preprint:1505.00308 (2015).

[147]

Domen Novak and Robert Riener. 2015. A survey of sensor fusion methods in wearable robotics. Robot. Auton. Syst. 73 (2015), 155--170.

Digital Library

[148]

Gyeongtaek Oh, Youdan Kim, Jaemyung Ahn, and Han-Lim Choi. 2016. PSO-based optimal task allocation for cooperative timing missions. IFAC-PapersOnLine 49, 17 (2016), 314--319.

[149]

Frans A. Oliehoek, Shimon Whiteson, and Matthijs T. J. Spaan. 2013. Approximate solutions for factored Dec-POMDPs with many agents. In Proceedings of the International Conference on Autonomous Agents 8 Multi-agent Syst. 563--570.

Digital Library

[150]

Anibal Ollero, Simon Lacroix, Luis Merino, Jeremi Gancet, Johan Wiklund, Volker Remuß, Iker Veiga Perez, Luis G. Gutiérrez, Domingos Xavier Viegas, Miguel Angel González Benitez, et al. 2005. Multiple eyes in the skies: Architecture and perception issues in the COMETS unmanned air vehicles project. IEEE Robot. Autom. Mag. 12, 2 (2005), 46--57.

[151]

Shayegan Omidshafiei, Jason Pazis, Christopher Amato, Jonathan P. How, and John Vian. 2017. Deep decentralized multi-task multi-agent reinforcement learning under partial observability. In Proceedings of the International Conference on Machine Learning. 2681--2690.

Digital Library

[152]

Jun Ota. 2006. Multi-agent robot systems as distributed autonomous systems. Adv. Eng. Inf. 20, 1 (2006), 59--70.

Digital Library

[153]

M. Padmanabhan and G. R. Suresh. 2015. Coalition formation and task allocation of multiple autonomous robots. In Proceedings of the IEEE 3rd International Conference on Signal Processing, Communication and Networking. 1--5.

[154]

Narendra Singh Pal and Sanjeev Sharma. 2013. Robot path planning using swarm intelligence: A survey. Int. J. Comput. Applicat. 83, 12 (2013).

[155]

Liviu Panait and Sean Luke. 2005. Cooperative multi-agent learning: The state of the art. Auton. Agents Multi-Agent Syst. 11, 3 (2005), 387--434.

Digital Library

[156]

Lynne E. Parker. 2008. Distributed intelligence: Overview of the field and its application in multi-robot systems. J. Phys. Agents 2, 1 (2008), 5--14.

[157]

Lynne E. Parker. 2008. Multiple mobile robot systems. In Springer Handbook of Robotics. Springer, 921--941.

[158]

Lynne E. Parker and Fang Tang. 2006. Building multirobot coalitions through automated task solution synthesis. Proc. IEEE 94, 7 (2006), 1289--1305.

[159]

Liam Paull, Guoquan Huang, Mae Seto, and John J. Leonard. 2015. Communication-constrained multi-AUV cooperative SLAM. In Proceedings of the IEEE International Conference on Robotics and Automation. 509--516.

[160]

Markus Peters, Wolfgang Ketter, Maytal Saar-Tsechansky, and John Collins. 2013. A reinforcement learning approach to autonomous decision-making in smart electricity markets. Mach. Learn. 92, 1 (2013), 5--39.

Digital Library

[161]

Charles Pippin, Henrik Christensen, and Lora Weiss. 2013. Performance based task assignment in multi-robot patrolling. In Proceedings of the 28th Annual ACM Symposium on Applied Computing. ACM, 70--76.

Digital Library

[162]

Charles Pippin, Gary Gray, Michael Matthews, Dave Price, Ai-Ping Hu, Warren Lee, Michael Novitzky, and Paul Varnell. 2010. The Design of an Air-ground Research Platform for Cooperative Surveillance. Technical Report. Tech. Rep. 112010, Georgia Tech Research Institute.

[163]

Sameera Ponda, Josh Redding, Han-Lim Choi, Jonathan P. How, Matt Vavrina, and John Vian. 2010. Decentralized planning for complex missions with dynamic communication constraints. In Proceedings of the IEEE American Control Conference. 3998--4003.

[164]

David Portugal and Rui Rocha. 2011. A survey on multi-robot patrolling algorithms. In Proceedings of the Doctoral Conference on Computing, Elect. 8 Ind. Syst. Springer, 139--146.

[165]

David Portugal and Rui P. Rocha. 2016. Cooperative multi-robot patrol with Bayesian learning. Auton. Robots 40, 5 (2016), 929--953.

Digital Library

[166]

K. J. Prabuchandran, A. N. Hemanth Kumar, and Shalabh Bhatnagar. 2014. Multi-agent reinforcement learning for traffic signal control. In Proceedings of the 17th International Conference on Intelligent Transportation Systems. IEEE, 2529--2534.

[167]

Marc Pujol-Gonzalez, Jesus Cerquides, Alessandro Farinelli, Pedro Meseguer, and Juan Antonio Rodriguez-Aguilar. 2015. Efficient inter-team task allocation in robocup rescue. In Proceedings of the International Conference on Autonomous Agents and Multiagent Systems. International Foundation for Autonomous Agents 8 Multiagent Syst., 413--421.

Digital Library

[168]

Martin L. Puterman. 2014. Markov Decision Processes: Discrete Stochastic Dynamic Programming. John Wiley 8 Sons, New York, NY.

[169]

Binsen Qian and Harry H. Cheng. 2014. A bio-inspired mobile agent-based coalition formation system for multiple modular-robot systems. In Proceedings of the IEEE/ASME 10th International Conference on Mechatronic and Embedded Systems and Applications. 1--6.

[170]

Binsen Qian and Harry H. Cheng. 2016. A mobile agent-based coalition formation system for multi-robot systems. In Proceedings of the 12th IEEE/ASME International Conference on Mechatronic and Embedded Systems and Applications. 1--6.

[171]

Richard J. Radke. 2010. A survey of distributed computer vision algorithms. In Handbook of Ambient Intelligence and Smart Environments. Springer, 35--55.

[172]

Reihane Rahimi, Farzaneh Abdollahi, and Karo Naqshi. 2014. Time-varying formation control of a collaborative heterogeneous multi agent system. Robot. Auton. Syst. 62, 12 (2014), 1799--1805.

Digital Library

[173]

Sarvapali D. Ramchurn, Maria Polukarov, Alessandro Farinelli, Cuong Truong, and Nicholas R. Jennings. 2010. Coalition formation with spatial and temporal constraints. In Proceedings of the 9th International Conference on Autonomous Agents 8 Multiagent Syst., Vol. 3. 1181--1188.

Digital Library

[174]

Partha Pratim Ray. 2016. Internet of robotic things: Concept, technologies, and challenges. IEEE Access 4 (Dec 2016), 9489--9500.

[175]

Luis Riazuelo, Moritz Tenorth, Daniel Di Marco, Marta Salas, Dorian Gálvez-López, Mösenlechner, et al. 2015. Roboearth semantic mapping: A cloud enabled knowledge-based approach. IEEE Trans. Autom. Sci. Eng. 12, 2 (2015), 432--443.

[176]

Yara Rizk and Mariette Awad. 2019. On extreme learning machines in sequential and time series prediction: A non-iterative and approximate training algorithm for recurrent neural networks. Neurocomputing 325 (Jan. 2019), 1--19.

[177]

Yara Rizk, Mariette Awad, and Edward Tunstel. 2018. Decision making in multi agent systems: A survey. Trans. Cogn. Dev. Syst. 10, 3 (2018), 514--529.

[178]

Cyril Robin and Simon Lacroix. 2016. Multi-robot target detection and tracking: Taxonomy and survey. Auton. Robots 40, 4 (2016), 729--760.

Digital Library

[179]

Florian Rohrmüller, Dirk Wollherr, and Martin Buss. 2012. Muroco: A framework for capability-and situation-aware coalition formation in cooperative multi-robot systems. J. Intell. Robot. Syst. 67, 3--4 (2012), 339--370.

[180]

Juan Jesús Roldán, Pablo Garcia-Aunon, Mario Garzón, Jorge de León, Jaime del Cerro, and Antonio Barrientos. 2016. Heterogeneous multi-robot system for mapping environmental variables of greenhouses. Sensors 16, 7 (2016), 1018.

[181]

Lorenzo Rosa, Marco Cognetti, Andrea Nicastro, Pol Alvarez, and Giuseppe Oriolo. 2015. Multi-task cooperative control in a heterogeneous ground-air robot team. IFAC J. Syst. Contr. 48, 5 (2015), 53--58.

[182]

Asim Roy. 2008. Connectionism, controllers, and a brain theory. IEEE Trans. Syst. Man Cybern. A., Syst. Hum. 38, 6 (2008), 1434--1441.

Digital Library

[183]

Asim Roy. 2010. On NSF “open questions,” some external properties of the brain as a learning system and an architecture for autonomous learning. In Proceedings of the International Joint Conference on Neural Networks. IEEE, 1--8.

[184]

Stuart Russell and Peter Norvig. 2009. Artificial Intelligence: A Modern Approach. Pearson.

Digital Library

[185]

Lorenzo Sabattini, Cristian Secchi, and Cesare Fantuzzi. 2016. Coordinated dynamic behaviors for multirobot systems with collision avoidance. IEEE Trans. Cybern. 47, 12 (2016), 4062--4073.

[186]

Adam Sadilek, John Krumm, and Eric Horvitz. 2013. Crowdphysics: Planned and opportunistic crowdsourcing for physical tasks. J. Sea Res. 21, 10,424 (2013), 125--620.

[187]

Joao Machado Santos, Micael S. Couceiro, David Portugal, and Rui P. Rocha. 2014. Fusing sonars and LRF data to perform SLAM in reduced visibility scenarios. In Proceedings of the IEEE International Conference on Autonomous Robot Systems and Competitions. 116--121.

[188]

João Machado Santos, Micael S. Couceiro, David Portugal, and Rui P. Rocha. 2015. A sensor fusion layer to cope with reduced visibility in SLAM. J. Intell. Robot. Syst. 80, 3--4 (2015), 401--422.

Digital Library

[189]

Sanem Sariel-Talay, Tucker R. Balch, and Nadia Erdogan. 2011. A generic framework for distributed multirobot cooperation. J. Intell. Robot. Syst. 63, 2 (2011), 323--358.

Digital Library

[190]

Mahadev Satyanarayanan. 2017. The emergence of edge computing. Computer 50, 1 (2017), 30--39.

Digital Library

[191]

Jun Sawada, Filipp Akopyan, Andrew S. Cassidy, Brian Taba, Michael V. Debole, Pallab Datta, Rodrigo Alvarez-Icaza, Arnon Amir, John V. Arthur, Alexander Andreopoulos, et al. 2016. Truenorth ecosystem for brain-inspired computing: Scalable systems, software, and applications. In Proceedings of the International Conference for High Performance Computing, Networking, Storage and Analysis. IEEE Press, 12.

Digital Library

[192]

Sayan D. Sen and Julie A. Adams. 2015. An influence diagram based multi-criteria decision making framework for multirobot coalition formation. Auton. Agents Multi-Agent Syst. 29, 6 (2015), 1061--1090.

Digital Library

[193]

Travis C. Service, Sayan D. Sen, and Julie A. Adams. 2014. A simultaneous descending auction for task allocation. In Proceedings of the IEEE International Conference on Systems, Man and Cybernetics. 379--384.

[194]

Lloyd S. Shapley. 1953. Stochastic games. Proc. Natl. Acad. Sci. U.S.A. 39, 10 (1953), 1095.

[195]

Pedro M. Shiroma and Mario F. M. Campos. 2009. CoMutaR: A framework for multi-robot coordination and task allocation. In Proceedings of the IEEE/RSJ International Conference on Intelligent Robots and Systems. 4817--4824.

Digital Library

[196]

Yoav Shoham and Kevin Leyton-Brown. 2008. Multiagent Systems: Algorithmic, Game-theoretic, and Logical Foundations. Cambridge University Press.

[197]

David Silver and Joel Veness. 2010. Monte-Carlo planning in large POMDPs. In Advances in Neural Information Processing Systems. 2164--2172.

Digital Library

[198]

Reid Simmons, Sanjiv Singh, David Hershberger, Josue Ramos, and Trey Smith. 2001. First results in the coordination of heterogeneous robots for large-scale assembly. In Experimental Robotics VII. Springer, 323--332.

Digital Library

[199]

Pieter Simoens, Christof Mahieu, Femke Ongenae, Femke De Backere, Stijn De Pestel, Jelle Nelis, Filip De Turck, Shirley A. Elprama, Katriina Kilpi, Charlotte Jewell, et al. 2016. Internet of robotic things: Context-aware and personalized interventions of assistive social robots (short paper). In Proceedings of the 2016 5th IEEE International Conference on Cloud Networking (Cloudnet’16). IEEE, 204--207.

[200]

Rubén Solera-Urena, Ana Isabel Garcia-Moral, Carmen Peláez-Moreno, Manel Martinez-Ramon, and Fernando Diaz-de Maria. 2012. Real-time robust automatic speech recognition using compact support vector machines. IEEE Trans. Aud. Speech Lang. Process. 20, 4 (2012), 1347--1361.

Digital Library

[201]

Lei Song, Fan Jiang, Zhongke Shi, Rafael Molina, and Aggelos K. Katsaggelos. 2014. Toward dynamic scene understanding by hierarchical motion pattern mining. IEEE Trans. Intell. Transp. Syst. 15, 3 (2014), 1273--1285.

[202]

Zhao Song, Xuejun Liao, and Lawrence Carin. 2015. Solving DEC-POMDPs by expectation maximization of value functions. AAAI Spring Symposium Series (2015), 68--76.

[203]

Matthijs T. J. Spaan, Frans A. Oliehoek, and Christopher Amato. 2011. Scaling Up optimal heuristic search in Dec-POMDPs via incremental expansion. In Proceedings of the 22nd International Joint Conference on Artificial Intelligence.

Digital Library

[204]

Paolo Stegagno, Marco Cognetti, L. S. Rosa, Pietro Peliti, and Giuseppe Oriolo. 2013. Relative localization and identification in a heterogeneous multi-robot system. In Proceedings of the IEEE International Conference on Robotics and Automation. 1857--1864.

[205]

Peter Stone and Manuela Veloso. 2000. Multiagent systems: A survey from a machine learning perspective. Auton. Robots 8, 3 (2000), 345--383.

Digital Library

[206]

Xueqing Sun, Tao Mao, and Laura E. Ray. 2009. Inference model for heterogeneous robot team configuration based on Reinforcement Learning. In Proceedings of the IEEE International Conference on Technologies for Practical Robot Applications. 55--60.

[207]

Toshihisa Tabuchi, Seiichi Ozawa, and Asim Roy. 2009. An autonomous learning algorithm of resource allocating network. In Proceedings of the International Conference on Intelligence Data Engineering and Automated Learning. Springer, 134--141.

Digital Library

[208]

Ayesha M. Talha and Imran N. Junejo. 2014. Dynamic scene understanding using temporal association rules. Image Vis. Comput. 32, 12 (2014), 1102--1116.

Digital Library

[209]

Zheng-Hua Tan and Børge Lindberg. 2010. Low-complexity variable frame rate analysis for speech recognition and voice activity detection. IEEE J. Sel. Top. Sign. Process. 4, 5 (2010), 798--807.

[210]

Biwei Tang, Zhanxia Zhu, Hyo-Sang Shin, and Antonios Tsourdos. 2015. Task-priority based task allocation of multiple UAVs with resource constraint. In Proceedings of the 23th Mediterranean Conference on Control and Automation. IEEE, 8--13.

[211]

Su-Yan Tang, Yi-Fan Zhu, Qun Li, and Yong-Lin Lei. 2010. Survey of task allocation in multi agent systems. Syst. Eng. Electron. 32, 10 (2010), 2155--2161.

[212]

Adam Taylor, Ivana Dusparic, Edgar Galván-López, Siobhán Clarke, and Vinny Cahill. 2013. Transfer learning in multi-agent systems through parallel transfer. In Proceedings of the 30th International Conference on Machine Learning. 1--9.

[213]

Matthew E. Taylor and Peter Stone. 2009. Transfer learning for reinforcement learning domains: A survey. J. Mach. Learn. Res. 10 (Jul. 2009), 1633--1685.

Digital Library

[214]

Dušan Teodorović and Mauro Dell’Orco. 2005. Bee colony optimization--a cooperative learning approach to complex transportation problems. In Advanced OR and AI Methods in Transportation. 51--60.

[215]

Alejandro Torreño, Eva Onaindia, Antonín Komenda, and Michal Štolba. 2018. Cooperative multi-agent planning: A survey. ACM Comput. Surv. 50, 6 (2018), 84.

Digital Library

[216]

J. Gregory Trafton, Laura M. Hiatt, Anthony M. Harrison, Franklin P. Tamborello II, Sangeet S. Khemlani, and Alan C. Schultz. 2013. Act-r/e: An embodied cognitive architecture for human-robot interaction. J. Hum.-Robot Interact. 2, 1 (2013), 30--55.

Digital Library

[217]

Nicolas A. Tsokas and Kostas J. Kyriakopoulos. 2012. Multi-robot multiple hypothesis tracking for pedestrian tracking. Auton. Robots 32, 1 (2012), 63--79.

Digital Library

[218]

Richard T. Vaughan, Gaurav S. Sukhatme, Francisco J. Mesa-Martinez, and James F. Montgomery. 2000. Fly spy: Lightweight localization and target tracking for cooperating air and ground robots. In Distributed Autonomous Robotic Systems 4. Springer, Berlin, 315--324.

[219]

Sarvesh Vishwakarma and Anupam Agrawal. 2013. A survey on activity recognition and behavior understanding in video surveillance. Vis. Comput. 29, 10 (2013), 983--1009.

[220]

Chao Wang, Lei Gong, Qi Yu, Xi Li, Yuan Xie, and Xuehai Zhou. 2017. DLAU: A scalable deep learning accelerator unit on FPGA. IEEE Trans. Comput.-Aid. Des. Integr. Circ. Syst. 36, 3 (2017), 513--517.

Digital Library

[221]

Chaohui Wang, Nikos Komodakis, and Nikos Paragios. 2013. Markov random field modeling, inference 8 learning in computer vision 8 image understanding: A survey. Comput. Vis. Image Understand. 117, 11 (2013), 1610--1627.

Digital Library

[222]

L. Wang, M. Liu, and M. Q. Meng. 2017. A hierarchical auction-based mechanism for real-time resource allocation in cloud robotic systems. IEEE Trans. Cybern. 47, 2 (2017), 473--484.

[223]

Qining Wang, Ming Wu, Yan Huang, and Long Wang. 2008. Formation control of heterogeneous multi-robot systems. IFAC Proc. Vol. 41, 2 (2008), 6596--6601.

[224]

Wanyuan Wang, Jiuchuan Jiang, Bo An, Yichuan Jiang, and Bing Chen. 2017. Toward efficient team formation for crowdsourcing in noncooperative social networks. IEEE Trans. Cybern. 47, 12 (2017), 4208--4222.

[225]

Sarah E. Webster, Jeffrey M. Walls, Louis L. Whitcomb, and Ryan M. Eustice. 2013. Decentralized extended information filter for single-beacon cooperative acoustic navigation: Theory and experiments. IEEE Trans. Robot. 29, 4 (2013), 957--974.

Digital Library

[226]

Gerhard Weiss (Ed.). 2013. Multiagent Systems. MIT Press.

Digital Library

[227]

Shimon Whiteson. 2012. Evolutionary computation for reinforcement learning. In Reinforcement Learning. Springer, Berlin, 325--355.

[228]

Joey Wilson and Neal Patwari. 2011. See-through walls: Motion tracking using variance-based radio tomography networks. IEEE Trans. Mobile Comput. 10, 5 (2011), 612--621.

Digital Library

[229]

Jinseok Woo, Kazuyoshi Wada, and Naoyuki Kubota. 2012. Robot partner system for elderly people care by using sensor network. In Proceedings of the 4th IEEE RAS and EMBS International Conference on Biomedical Robotics and Biomechatronics. 1329--1334.

[230]

Bo Xu, Zhaofeng Yang, Yu Ge, and Zhiping Peng. 2015. Coalition formation in multi-agent systems based on improved particle swarm optimization algorithm. Int. J. Hybrid Inf. Technol. 8, 3 (2015).

[231]

Zhi Yan, Nicolas Jouandeau, and Arab Ali Cherif. 2013. A survey and analysis of multi-robot coordination. Int. J. Adv. Robot. Syst. 10 (2013).

[232]

Zhang Yu, Liu Shuhua, Fu Shuai, and Wu Di. 2009. A quantum-inspired ant colony optimization for robot coalition formation. In Proceedings of the Chinese Control and Decision Conference. IEEE, 626--631.

Digital Library

[233]

Yu Zhang and Lynne E. Parker. 2013. IQ-ASyMTRe: Forming executable coalitions for tightly coupled multirobot tasks. IEEE Trans. Robot. 29, 2 (2013), 400--416.

Digital Library

[234]

Z. Zhang, D. Zhao, J. Gao, D. Wang, and Y. Dai. 2017. FMRQ-A multiagent reinforcement learning algorithm for fully cooperative tasks. IEEE Trans. Cybern. 47, 6 (2017), 1367--1379.

[235]

Yuanshi Zheng and Long Wang. 2012. Distributed consensus of heterogeneous multi-agent systems with fixed and switching topologies. Int. J. Contr. 85, 12 (2012), 1967--1976.

[236]

Yuanshi Zheng and Long Wang. 2014. Containment control of heterogeneous multi-agent systems. Int. J. Contr. 87, 1 (2014), 1--8.

[237]

Y. Zheng, Y. Zhu, and L. Wang. 2011. Consensus of heterogeneous multi-agent systems. IET Contr. Theory Applicat. 5, 16 (2011), 1881--1888.

[238]

Liu Zhong, Gao Xiao-Guang, and Fu Xiao-Wei. 2015. Coalition formation for multiple heterogeneous UAVs in unknown environment. In Proceedings of the IEEE 5th International Conference on Instrumentation and Measurement, Computer, Communication and Control. 1222--1227.

[239]

Kai Zhou, Karthik Mahesh Varadarajan, Michael Zillich, and Markus Vincze. 2011. Web mining driven semantic scene understanding and object localization. In Proceedings of the IEEE International Conference on Robotics and Biomimetics. 2824--2829.

[240]

L. Zhou, P. Yang, C. Chen, and Y. Gao. 2017. Multiagent reinforcement learning with sparse interactions by negotiation and knowledge transfer. IEEE Trans. Cybern. 47, 5 (2017), 1238--1250.

[241]

Robert Zlot and Anthony Stentz. 2003. Multirobot control using task abstraction in a market framework. In Proceedings of the Collaborative Technology Alliances Conference.

[242]

Robert Zlot and Anthony Stentz. 2005. Complex task allocation for multiple robots. In Proceedings of the IEEE International Conference on Robotics and Automation. 1515--1522.

[243]

Robert Zlot and Anthony Stentz. 2006. Market-based multirobot coordination for complex tasks. Int. J. Robot. Research 25, 1 (2006), 73--101.

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Index Terms

Cooperative Heterogeneous Multi-Robot Systems: A Survey
1. Computing methodologies
  1. Artificial intelligence
    1. Distributed artificial intelligence
      1. Multi-agent systems
    2. Planning and scheduling
      1. Multi-agent planning
      2. Robotic planning

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As the community strives towards autonomous multi-robot systems, there is a need for these systems to autonomously form coalitions to complete assigned missions. Numerous coalition formation algorithms have been proposed in the software agent ...
Coalition Formation: From Software Agents to Robots

A problem that has recently attracted the attention of the research community is the autonomous formation of robot teams to perform complex multi-robot tasks. The corresponding problem for software agents is also known in the multi-agent community as ...
Methods for task allocation via agent coalition formation

Task execution in multi-agent environments may require cooperation among agents. Given a set of agents and a set of tasks which they have to satisfy, we consider situations where each task should be attached to a group of agents that will perform the ...

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Published In

cover image ACM Computing Surveys

ACM Computing Surveys Volume 52, Issue 2

March 2020

770 pages

ISSN:0360-0300

EISSN:1557-7341

DOI:10.1145/3320149

Editor:
Sartaj Sahni
Department of Computer and Information Science and Engineering

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Copyright © 2019 ACM.

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Association for Computing Machinery

New York, NY, United States

Publication History

Published: 09 April 2019

Accepted: 01 January 2019

Revised: 01 January 2019

Received: 01 January 2018

Published in CSUR Volume 52, Issue 2

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American University of Beirut
National Council of Scientific Research in Lebanon (CNRS-L)
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Lee GLee DLim Y(2024)Task Allocation for Heterogeneous Multi-Robot Systems with Diverse Capabilities2024 24th International Conference on Control, Automation and Systems (ICCAS)10.23919/ICCAS63016.2024.10773254(1599-1600)Online publication date: 29-Oct-2024
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Uemura YNarita RKurashige K(2024)Effective Action Learning Method Using Information Entropy for a Single Robot Under Multi-Agent ControlJournal of Advanced Computational Intelligence and Intelligent Informatics10.20965/jaciii.2024.p027328:2(273-283)Online publication date: 20-Mar-2024
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NAGAE KUSHIO T(2024)Extension of Counting LTL and Its Application to a Path Planning Problem for Heterogeneous Multi-Robot SystemsIEICE Transactions on Fundamentals of Electronics, Communications and Computer Sciences10.1587/transfun.2023MAI0001E107.A:5(752-761)Online publication date: 1-May-2024
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