UAVs Beneath the Surface: Cooperative Autonomy for Subterranean Search and Rescue in DARPA SubT

Petrlík, Matěj; Petráček, Pavel; Krátký, Vít; Musil, Tomáš; Stasinchuk, Yurii; Vrba, Matouš; Báča, Tomáš; Heřt, Daniel; Pecka, Martin; Svoboda, Tomáš; Saska, Martin

doi:10.55417/fr.2023001

Cited by 9 publications

(14 citation statements)

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“…The amount of misclassified space could be reduced by choosing different bounding shapes, such as polygons or 6DOF boxes, which would better approximate the segments' shapes at the expense of higher computational complexity and higher communication bandwidth. Nevertheless, for the purposes of decentralized cooperative planning, we found the 4DOF boxes to be sufficient in the DARPA SubT Challenge [22].…”

Section: Map Compression Analysismentioning

confidence: 92%

“…• a novel dynamically built graph structure (SphereMap) with clearance information that allows for rapid safetyaware path planning between any two points in known space and can handle arbitrarily structured and changing environments, • a method for quickly generating a lightweight volumetric graph representation (LTVMap) of the environment, that can be shared with other robots using low-bandwidth communication and carry mission-critical information, • experimental evaluation showing that planning on the SphereMap can be orders of magnitude faster than stateof-the-art approaches for long-distance planning, • validation of the proposed methods in real world scenarios, most importantly in the DARPA SubT competition, where robots were deployed into both real and simulated previously unvisited environments [22].…”

Section: B Contributionsmentioning

confidence: 99%

“…For SAR missions, additional information (such as the percentage of surfaces covered by the UAV's cameras or information about frontiers in a given region) can easily be appended to each region. This information can then be shared with other robots during the mission for cooperation purposes, and also with human operators to whom this map representation can provide a good overview of the environment and the mission progress [22].…”

Section: Lightweight Map Creation and Sharingmentioning

confidence: 99%

“…The control and state estimation part of the deployed system is described further in [4]. The SphereMap in a more crude form (without pruning of nodes) was used also in the virtual circuit of the DARPA SubT Challenge Finals, where our team CTU-CRAS-NORLAB won the 2 nd place [22]. Lastly, the SphereMap was also tested on a large outdoor environment where a UAV autonomously explored the space around a house surrounded by heavy shrubbery, crossed a bridge into a vast open field, and safely returned home.…”

Section: Real World Deploymentmentioning

confidence: 99%

See 3 more Smart Citations

SphereMap: Dynamic Multi-Layer Graph Structure for Rapid Safety-Aware UAV Planning

Musil

Petrlík

Saska

2022

IEEE Robot. Autom. Lett.

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A flexible topological representation consisting of a two-layer graph structure built on-board an Unmanned Aerial Vehicle (UAV) by continuously filling the free space of an occupancy map with intersecting spheres is proposed in this letter. Most state-of-the-art planning methods find the shortest paths while keeping the UAV at a pre-defined distance from obstacles. Planning over the proposed structure reaches this pre-defined distance only when necessary, maintaining a safer distance otherwise, while also being orders of magnitude faster than other stateof-the-art methods. Furthermore, we demonstrate how this graph representation can be converted into a lightweight shareable topological-volumetric map of the environment, which enables decentralized multi-robot cooperation. The proposed approach was successfully validated in several kilometers of real subterranean environments, such as caves, devastated industrial buildings, and in the harsh and complex setting of the final event of the DARPA SubT Challenge, which aims to mimic the conditions of real search and rescue missions as closely as possible, and where our approach achieved the 2 nd place in the virtual track.

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Section: Map Compression Analysismentioning

confidence: 92%

Section: B Contributionsmentioning

confidence: 99%

Section: Lightweight Map Creation and Sharingmentioning

confidence: 99%

Section: Real World Deploymentmentioning

confidence: 99%

See 2 more Smart Citations

SphereMap: Dynamic Multi-Layer Graph Structure for Rapid Safety-Aware UAV Planning

Musil

Petrlík

Saska

2022

IEEE Robot. Autom. Lett.

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“…We finished second in the virtual track, and we achieved sixth place in the competition with physical robots, where three UAVs together with six UGVs found seven artifacts in a complex confined environment. The developed approach is extensively covered by [29,68]. The platform also proved its reliability in intensive tests in intricate environments, such as vast natural caves, ruins of industrial buildings, underground fortresses, mining tunnels, and large-scale outdoor environments with dense vegetation.…”

Section: Darpa Subterranean Challenge -Sandr Competition In Undergrou...mentioning

confidence: 99%

MRS Drone: A Modular Platform for Real-World Deployment of Aerial Multi-Robot Systems

Heřt

Báča

Petráček

et al. 2023

J Intell Robot Syst

Self Cite

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This paper presents a modular autonomous Unmanned Aerial Vehicle (UAV) platform called the Multi-robot Systems (MRS) Drone that can be used in a large range of indoor and outdoor applications. The MRS Drone features unique modularity with respect to changes in actuators, frames, and sensory configuration. As the name suggests, the platform is specially tailored for deployment within a MRS group. The MRS Drone contributes to the state-of-the-art of UAV platforms by allowing smooth real-world deployment of multiple aerial robots, as well as by outperforming other platforms with its modularity. For real-world multi-robot deployment in various applications, the platform is easy to both assemble and modify. Moreover, it is accompanied by a realistic simulator to enable safe pre-flight testing and a smooth transition to complex real-world experiments. In this manuscript, we present mechanical and electrical designs, software architecture, and technical specifications to build a fully autonomous multi UAV system. Finally, we demonstrate the full capabilities and the unique modularity of the MRS Drone in various real-world applications that required a diverse range of platform configurations.

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An autonomous UAV system based on adaptive LiDAR inertial odometry for practical exploration in complex environments

Kim,

Azhari,

Park

et al. 2024

Journal of Field Robotics

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Unmanned aerial vehicles (UAVs) offer many advantages over ground vehicles, including quadruped robots, based on high maneuverability when performing exploration in complex and unknown environments. However, due to their limited computational capability, UAVs require lightweight but accurate state estimation algorithms for reliable exploration. In this paper, we propose a segmented map‐based exploration system based on light detection and ranging (LiDAR)‐based state estimation for UAVs. The proposed system includes capabilities such as exploration, obstacle avoidance, and object detection with localization using three‐dimensional (3D) dense maps generated by tightly coupled LiDAR Inertial Odometry (LIO). Our proposed system is a hybrid system that can switch between guided and exploration modes, making it practical for search and rescue missions in disaster scenarios. The proposed LIO algorithm adapts to its surroundings, allowing for fast and accurate state estimation in complex environments. The proposed exploration algorithm is designed to cover specific regions in the 3D dense map generated by the proposed LIO, with the UAV determining if map points are included within the coverage area. We tested the proposed system in both simulation and real‐world environments and validated that the proposed system outperforms state‐of‐the‐art algorithms in various aspects such as localization accuracy and exploration efficiency in complex environments.

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UAVs Beneath the Surface: Cooperative Autonomy for Subterranean Search and Rescue in DARPA SubT

Cited by 9 publications

References 0 publications

SphereMap: Dynamic Multi-Layer Graph Structure for Rapid Safety-Aware UAV Planning

SphereMap: Dynamic Multi-Layer Graph Structure for Rapid Safety-Aware UAV Planning

MRS Drone: A Modular Platform for Real-World Deployment of Aerial Multi-Robot Systems

An autonomous UAV system based on adaptive LiDAR inertial odometry for practical exploration in complex environments

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