Connectivity-Maintenance Teleoperation of a UAV Fleet With Wearable Haptic Feedback

Aggravi, Marco; Pacchierotti, Claudio; Giordano, Paolo Robuffo

doi:10.1109/tase.2020.3000060

Cited by 20 publications

(17 citation statements)

References 48 publications

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“…To the best of our knowledge, there are no examples of complex interactions between multiple humans and robots in this scenario. On the other hand, we can find several examples of human operators teleoperating one or more mobile robots [13], [32], [12], [33], [34], [35], [36]. For example, Setter et al [33] proposed a multi-agent manipulability concept, mapping the forces commanded by the operator through a grounded haptic interface to the motion of a swarm of mobile robots and viceversa.…”

Section: Related Workmentioning

confidence: 99%

“…The user controls the robot by modifying, at runtime, the trajectory along which the robot is navigating, while an autonomous algorithm ensures that no collisions occur, the path remains smooth, and some points of interest are visited. In [36], we proposed a decentralized connectivity-maintenance algorithm for the teleoperation of a team of multiple UAVs. With respect to this work, [36] considered a pure teleoperation approach, where the human operator is remotely controlling the formation.…”

Section: Related Workmentioning

confidence: 99%

“…In [36], we proposed a decentralized connectivity-maintenance algorithm for the teleoperation of a team of multiple UAVs. With respect to this work, [36] considered a pure teleoperation approach, where the human operator is remotely controlling the formation. Here, in contrast, we focus on the inclusion of the operator in the team of robots, aiming at achieving increased situational awareness and faster reaction time from the human agent.…”

Section: Related Workmentioning

confidence: 99%

“…In this work we exploit the connectivity maintenance control strategy originally proposed in [21] and later exploited in several works, e.g., [36]. Indeed, this strategy is general enough for allowing the inclusion of many constraints/requirements of interest into a single generalized connectivity maintenance action, and it also easily allows for the presence of additional external inputs that can be used to steer the individual robots in the group in performing their own mission besides the sole connectivity maintenance constraint.…”

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confidence: 99%

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Decentralized Control of a Heterogeneous Human–Robot Team for Exploration and Patrolling

Aggravi

Sirignano

Giordano

et al. 2022

IEEE Trans. Automat. Sci. Eng.

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We present a decentralized connectivity-maintenance control framework for an heterogeneous human-robot team. The algorithm is able to manage a team composed of an arbitrary number of mobile robots (drones and ground robots in our case) and humans, for collaboratively achieving exploration and patrolling tasks. Differently from other works on the subject, here the human user physically becomes part of the team, moving in the same environment of the robots and receiving information about the team connectivity through wearable haptics or audio feedback. While the human explores the environment, the robots move so as to keep the team connected via a connectivitymaintenance algorithm; at the same time, each robot can also be assigned with a specific target to visit. We carried out three human subject experiments, both in virtual and real environments. Results show that the proposed approach is effective in a wide range of scenarios. Moreover, providing either haptic or audio feedback for conveying information about the team connectivity significantly improves the performance of the considered tasks, although users significantly preferred receiving haptic stimuli w.r.t. the audio ones.Note to Practitioners-Exploration, patrolling, and Search-and-Rescue are highly-dynamic and unstructured scenarios. When considering the operative conditions of such environments, the benefits of multi-robot systems are evident. Most tasks can be carried out faster and more robustly by a team of robots with respect to a single unit. There are also situations explicitly requiring the presence of a multi-robot team, e.g., using one drone for surveillance of the ground team and one ground mobile robot for carrying supplies. Of course, if the operator(s) in charge of the operation could share the same environment of the robots (i.e., be together with the robots in the field), they would be provided with a level of situational awareness that no teleoperation technology can match as of today. This work presents a framework for controlling heterogeneous teams composed of one human operator and an arbitrary number of aerial and ground mobile robots. The operator moves together with the robotic team and, at the same time, he or she receives meaningful information about the status of the formation. The algorithm only uses the relative position of the drones and humans with respect to each other, and all computations are designed in a decentralized fashion. Decentralization avoids relying on any absolute positioning system (e.g., GPS) or centralized command centers. These features make the proposed framework ready for deployment in different high-impact applications, such as in surveillance, search-and-rescue, and disaster response scenarios.

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Section: Related Workmentioning

confidence: 99%

Section: Related Workmentioning

confidence: 99%

Section: Related Workmentioning

confidence: 99%

mentioning

confidence: 99%

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Decentralized Control of a Heterogeneous Human–Robot Team for Exploration and Patrolling

Aggravi

Sirignano

Giordano

et al. 2022

IEEE Trans. Automat. Sci. Eng.

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“…Similarly, a robot pair (i, j) is also assumed able to exchange information over a radio channel when within the sensing range D u . Again, more complex sensing/communication constraints can also be considered, see [30], [31] for some examples. The group interaction is modeled with a directed sensing graph G(V, E), where V = {1, ..., N R } is the vertex set and E ⊆ V × V the edge set.…”

Section: B Sensing and Communication Modelmentioning

confidence: 99%

Online Decentralized Perception-Aware Path Planning for Multi-Robot Systems

Carli

Salaris²,

Giordano³

2021

2021 International Symposium on Multi-Robot and Multi-Agent Systems (MRS)

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This paper proposes a decentralized and online optimal perception-aware strategy for multi-robot systems. The aim is to maximize the information collected along the planned trajectory about the relative configurations of the robots and, hence, to minimize the localization uncertainty. This is done by leveraging the so-called Constructability Gramian (CG), which can quantify the information about the future state of a nonlinear system. We show that, thanks to a proper change of coordinates, the CG can be computed in a decentralized way with only minor approximations. This allows for formulating an online and decentralized trajectory generation problem for optimal localization. To show the effectiveness of the approach, we consider as case study the localization of a quadrotor group with noisy distance measurements and sensing constraints. The results show the interest of the proposed approach.

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UAV swarm formation reconfiguration control based on variable-stepsize MPC-APCMPIO algorithm

Liao,

Cheng,

Xin

et al. 2023

Sci. China Inf. Sci.

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Connectivity-Maintenance Teleoperation of a UAV Fleet With Wearable Haptic Feedback

Cited by 20 publications

References 48 publications

Decentralized Control of a Heterogeneous Human–Robot Team for Exploration and Patrolling

Decentralized Control of a Heterogeneous Human–Robot Team for Exploration and Patrolling

Online Decentralized Perception-Aware Path Planning for Multi-Robot Systems

UAV swarm formation reconfiguration control based on variable-stepsize MPC-APCMPIO algorithm

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