Heterogeneous Ground and Air Platforms, Homogeneous Sensing: Team CSIRO Data61’s Approach to the DARPA Subterranean Challenge

Hudson, Nicolas; Talbot, Fletcher; Cox, Michael; Williams, Jason L.; Hines, Thomas; Pitt, Alex; Wood, Brett; Frousheger, Dennis; Surdo, Katrina Lo; Molnar, Thomas J.; Steindl, Ryan; Wildie, Matt; Sa, Inkyu; Kottege, Navinda; Stepanas, Kazys; Hernández, Emili; Catt, Gavin; Docherty, William; Tidd, Brendan; Tam, Benjamin; Murrell, Simon; Bessell, Mitchell; Hanson, Lauren; Tychsen-Smith, Lachlan; Suzuki, Hajime; Overs, Leslie; Kendoul, Farid; Wagner, Glenn; Palmer, Duncan S.; Milani, Peter; O’Brien, Matthew; Jiang, Shengyuan; Chen, Shengkang; Arkin, Ronald C.

doi:10.55417/fr.2022021

Cited by 47 publications

(31 citation statements)

References 35 publications

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“…All data was collected with a Velodyne VLP-16 Puck lidar (either flat or spinning on a 30 • inclined pedestal), with dual return mode enabled. Sensor trajectory information is provided from the Wildcat SLAM pipeline described in [27]. This sensor produces around 300,000 rays/s.…”

Section: Resultsmentioning

confidence: 99%

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OHM: GPU Based Occupancy Map Generation

Stepanas¹,

Williams²,

Hernández³

et al. 2022

Preprint

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Occupancy grid maps (OGMs) are fundamental to most systems for autonomous robotic navigation. However, CPU-based implementations struggle to keep up with data rates from modern 3D lidar sensors, and provide little capacity for modern extensions which maintain richer voxel representations. This paper presents OHM, our open source, GPU-based OGM framework. We show how the algorithms can be mapped to GPU resources, resolving difficulties with contention to obtain a successful implementation. The implementation supports many modern OGM algorithms including NDT-OM, NDT-TM, decay-rate and TSDF. A thorough performance evaluation is presented based on tracked and quadruped UGV platforms and UAVs, and data sets from both outdoor and subterranean environments. The results demonstrate excellent performance improvements both offline, and for online processing in embedded platforms. Finally, we describe how OHM was a key enabler for the UGV navigation solution for our entry in the DARPA Subterranean Challenge, which placed second at the Final Event.

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Section: Resultsmentioning

confidence: 99%

“…The OHM implementation presented in this paper has been used widely in UGV navigation applications on wheeled, tracked, quadruped and hexapod platforms [27], as well as UAV navigation and planning and offline point cloud processing and filtering.…”

Section: A Applicationsmentioning

confidence: 99%

OHM: GPU Based Occupancy Map Generation

Stepanas¹,

Williams²,

Hernández³

et al. 2022

Preprint

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“…In multi-agent collaborative SLAM scenarios, each agent synchronises its database of submaps (containing submaps generated by itself and others) with other agents (i.e., other robots or the base station) within its communication range via peer-to-peer communication. We refer the reader to [6] for additional information about our ROS-based data sharing system, Mule. The maximum size of each submap with a lidar range of 100 m is about 500 KB, whereas the average submap size in underground SubT events was about 100-170 KB.…”

Section: A Submap Generationmentioning

confidence: 99%

“…The maximum size of each submap with a lidar range of 100 m is about 500 KB, whereas the average submap size in underground SubT events was about 100-170 KB. [6]. Therefore, Wildcat can easily share submaps between the agents with a modest communication bandwidth.…”

Section: A Submap Generationmentioning

confidence: 99%

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Wildcat: Online Continuous-Time 3D Lidar-Inertial SLAM

Ramezani¹,

Khosoussi²,

Catt³

et al. 2022

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We present Wildcat, a novel online 3D lidar-inertial SLAM system with exceptional versatility and robustness. At its core, Wildcat combines a robust real-time lidar-inertial odometry module, utilising a continuous-time trajectory representation, with an efficient pose-graph optimisation module that seamlessly supports both the single-and multi-agent settings. The robustness of Wildcat was recently demonstrated in the DARPA Subterranean Challenge where it outperformed other SLAM systems across various types of sensing-degraded and perceptually challenging environments. In this paper, we extensively evaluate Wildcat in a diverse set of new and publicly available real-world datasets and showcase its superior robustness and versatility over two existing state-of-the-art lidar-inertial SLAM systems.

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