Autonomous system for navigation and surveying in underground mines

Bakambu, J.N.; Polotski, Vladimir

doi:10.1002/rob.20213

Cited by 37 publications

(20 citation statements)

References 16 publications

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“…Our system does not require GPS positioning and therefore can be used underground or on obstructed construction sites. As compared to the system developed for mining applications in (Bakambu & Polotski, 2007), MRPTA uses more advanced positioning and planning algorithms and has more mapping capabilities.…”

Section: Discussionmentioning

confidence: 99%

Autonomous Navigation and Mapping System for MRPTA Rover

Polotski¹,

Ballotta²,

J.³

2013

Proceedings of the 30th International Symposium on Automation and Robotics in Construction and Mining (ISARC 2013): Building Th

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Initiated and financed by the Canadian Space Agency, Micro-Rover Platform with Tooling Arm (MRPTA) project has targeted the development of a robotic system with remote control and autonomous navigation capabilities for testing a large variety of analogous planetary missions. Although developed for planetary exploration, the navigation system is highly suitable to such areas of application as construction and in mining. Autonomous navigation system is capable of moving the platform to predefined position(s)/orientation(s) while continuously mapping the terrain, assessing its traversability and choosing most appropriate path to follow. Designed according to the JAUS (Joint Architecture for Unmanned Systems) framework, the system consists of several interconnected components. Following components are of particular importance: Pose Estimator (PE), Terrain Evaluator (TE), Map Manager (MP), and Path Planner (PP). The PE uses a minimal sensor configuration consisting of an azimuth gyroscope, inclinometer and wheel odometry. The PE provides reliable pose estimates in spite of pronounced slippage by employing extensive use of fused data. The TE uses a nodding laser scanner which continuously sweeps the area in front of the platform and constructs a "traversability grid" (TG) of the surrounding area. Multiple TGs are constantly constructed along the platform motion path are combined into a terrain map maintained by the MP. The PP uses this map to compute a motion path Obtained path is executed by the motion controller and remains current until it is contradicted by the most recent map -at which point it is re-planned. This paper addresses integration issues, lessons learned and also outlines the possible applications for construction and mining.

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Section: Discussionmentioning

confidence: 99%

Autonomous Navigation and Mapping System for MRPTA Rover

Polotski¹,

Ballotta²,

J.³

2013

Proceedings of the 30th International Symposium on Automation and Robotics in Construction and Mining (ISARC 2013): Building Th

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“…In fact, there are several examples of autotramming technologies employing reactive schemes and/or topological map representations in the literature (Bakambu & Polotski, 2007;Bakambu, Polotski, & Cohen, 2004;Debanné, Hervé, & Cohen, 1997;Duff, Roberts, Corke, & Cunningham, 2004;Roberts et al, 2000Roberts et al, , 2002Silver, Ferguson, Morris, & Thayer, 2004;Steele, Ganesh, & Kleve, 1993). Such technologies have also been combined with radio frequency identification (RFID) beacons to provide a global reference at key locations (Larsson, Broxvall, & Saffiotti, 2005).…”

Section: State Of the Artmentioning

confidence: 97%

Autonomous underground tramming for center‐articulated vehicles

Marshall

Barfoot

Larsson

2008

Journal of Field Robotics

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This paper describes the design, implementation, and field testing of an infrastructureless system for autonomous tramming (or hauling) of a center-articulated underground mining vehicle. Such vehicles are ubiquitous in underground mining, and effective automation of their tramming function has been a sought-after technology for more than a decade. This paper reports on the successful development of a fast, reliable, and robust "autotramming" technology that does not require the installation of fixed infrastructure. Included are descriptions of the chosen control architecture, map-based localization technique, and the results of integration and field testing. C 2008 Wiley Periodicals, Inc.

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“…In [8], the authors describe an autonomous robotics platform for the exploration of caves and mines. While some localization challenges are common to our addressed scenario, several aspects are peculiar to their specific application environment.…”

Section: Related Workmentioning

confidence: 99%

“…Input: costmap-boundary, global-stack Output: goal 1: local-stack ← ∅ 2: boundary-set-stack ← ∅ 3: for all P i ∈ costmap-boundary do scan/iterate in anticlockwise 4: if P i ∈ free space then 5: push(P i , boundary-set-stack) 6: end if 7: end for 8: if boundary-set-stack = ∅ then 9: for all P i ∈ boundary-set-stack do 10: S neigh ← ∅…”

Section: Algorithm 1 Map Edge Navigation Algorithmmentioning

confidence: 99%

Design of a Mobile Robot for Air Ducts Exploration

et al. 2017

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This work presents the solutions adopted for the design and the implementation of an autonomous wheeled robot developed for the exploration and mapping of air ventilation ducts. The hardware is based on commercial off-the-shelf devices, including sensors, motors, processing devices and interfaces. The mechanical chassis was designed from scratch to meet a trade-off between small size and available volume to host the components. The software stack is based on the Robot Operating System (ROS). Special attention was dedicated to the design of the mobility strategy, which must take into account some constraints and issues that are specific to the considered application, such as the relatively small size of ducts, the need to detect and avoid possible holes on the floor of the duct and other unusual obstacles and the unavailability of external reference frameworks for localization. The main contribution of this paper lies in the design, implementation and experimentation of the overall system.

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Autonomous system for navigation and surveying in underground mines

Cited by 37 publications

References 16 publications

Autonomous Navigation and Mapping System for MRPTA Rover

Autonomous Navigation and Mapping System for MRPTA Rover

Autonomous underground tramming for center‐articulated vehicles

Design of a Mobile Robot for Air Ducts Exploration

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