Formulating layered adjustable autonomy for unmanned aerial vehicles

Purpose The purpose of this paper is to propose a layered adjustable autonomy (LAA) as a dynamically adjustable autonomy model for a multi-agent system. It is mainly used to efficiently manage humans’ and agents’ shared control of autonomous systems and maintain humans’ global control over the agents. Design/methodology/approach The authors apply the LAA model in an agent-based autonomous unmanned aerial vehicle (UAV) system. The UAV system implementation consists of two parts: software and hardware. The software part represents the controller and the cognitive, and the hardware represents the computing machinery and the actuator of the UAV system. The UAV system performs three experimental scenarios of dance, surveillance and search missions. The selected scenarios demonstrate different behaviors in order to create a suitable test plan and ensure significant results. Findings The results of the UAV system tests prove that segregating the autonomy of a system as multi-dimensional and adjustable layers enables humans and/or agents to perform actions at convenient autonomy levels. Hence, reducing the adjustable autonomy drawbacks of constraining the autonomy of the agents, increasing humans’ workload and exposing the system to disturbances. Originality/value The application of the LAA model in a UAV manifests the significance of implementing dynamic adjustable autonomy. Assessing the autonomy within three phases of agents run cycle (task-selection, actions-selection and actions-execution) is an original idea that aims to direct agents’ autonomy toward performance competency. The agents’ abilities are well exploited when an incompetent agent switches with a more competent one.

[1]  Azhana Ahmad,et al.  A Conceptual Model of Layered Adjustable Autonomy , 2013, WorldCIST.

[2]  Daibing Zhang,et al.  Architecture Design and Performance Analysis of Supervisory Control System of Multiple UAVs , 2015 .

[3]  Sarvapali D. Ramchurn,et al.  Delivering the Smart Grid: Challenges for Autonomous Agents and Multi-Agent Systems Research , 2012, AAAI.

[4]  Lei Xue,et al.  A game theoretical approach for distributed resource allocation with uncertainty , 2017, Int. J. Intell. Comput. Cybern..

[5]  Nancy E. Reed,et al.  A User Controlled Approach to Adjustable Autonomy , 2005, Proceedings of the 38th Annual Hawaii International Conference on System Sciences.

[6]  Luigi Glielmo,et al.  A Markovian based approach for autonomous space systems , 2015, 2015 IEEE Metrology for Aerospace (MetroAeroSpace).

[7]  Sarvapali D. Ramchurn,et al.  A field study of human-agent interaction for electricity tariff switching , 2014, AAMAS.

[8]  Abdel-Illah Mouaddib,et al.  Integrating Human Recommendations in the Decision Process of Autonomous Agents , 2013, 2013 IEEE/WIC/ACM International Joint Conferences on Web Intelligence (WI) and Intelligent Agent Technologies (IAT).

[9]  Frédéric Vanderhaegen,et al.  Using adjustable autonomy and human-machine cooperation to make a human-machine system resilient - Application to a ground robotic system , 2011, Inf. Sci..

[10]  Ubbo Visser AI, Robotics and the Role of ECCAI , 2013, KI - Künstliche Intelligenz.

[11]  Maarten Sierhuis,et al.  Coactive design , 2014, J. Hum. Robot Interact..

[12]  Tamás Vicsek,et al.  Outdoor flocking and formation flight with autonomous aerial robots , 2014, 2014 IEEE/RSJ International Conference on Intelligent Robots and Systems.

[13]  L. A. M. Bush,et al.  Risk-based sensing in support of adjustable autonomy , 2012, 2012 IEEE Aerospace Conference.

[14]  Aida Mustapha,et al.  A Dynamic Measurement of Agent Autonomy in the Layered Adjustable Autonomy Model , 2014, Recent Developments in Computational Collective Intelligence.

[15]  Brahim Chaib-draa,et al.  Autonomous tactile perception: A combined improved sensing and Bayesian nonparametric approach , 2014, Robotics Auton. Syst..

[16]  Agostino Poggi,et al.  Developing Multi-agent Systems with JADE , 2007, ATAL.

[17]  Michael A. Goodrich,et al.  Sliding Autonomy for UAV Path-Planning: Adding New Dimensions to Autonomy Management , 2015, AAMAS.

[18]  Azhana Ahmad,et al.  A Dynamically Adjustable Autonomic Agent Framework , 2013, WorldCIST.

[19]  Monica Dragoicea,et al.  Integrating Agents and Services for Control and Monitoring: Managing Emergencies in Smart Buildings , 2014, Service Orientation in Holonic and Multi-Agent Manufacturing and Robotics.

[20]  Azhana Ahmad,et al.  An autonomy viability assessment matrix for agent-based autonomous systems , 2015, 2015 International Symposium on Agents, Multi-Agent Systems and Robotics (ISAMSR).

[21]  Marek Kisiel-Dorohinicki,et al.  Evolutionary multi-agent systems , 2015, The Knowledge Engineering Review.

[22]  Bin Li,et al.  A novel auto-adapted path-planning method for a shape-shifting robot , 2011, Int. J. Intell. Comput. Cybern..