An Intelligent, Heuristic Path Planner for Multiple Agent Unmanned Air Systems

Crispin, Chris; Sóbester, András

doi:10.2514/6.2015-0361

Cited by 7 publications

(5 citation statements)

References 10 publications

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“…Also several biologically inspired methods exist [27,28,29], and some use potential field based approaches in unstructured environments [30] that is beneficial when unexpected obstacles appear, but requires the tuning of several parameters to adopt to different settings. When the motion capabilities are limited as for fixed-wing UAVs, performing a tree search within the feasible paths can be used to control the vehicles [17,31,32] (detailed in Section 2.4). Unfortunately, to use such techniques for long-term online planning, the action space has to be significantly reduced by either discretising the problem [16] or limiting the action space to a set of predefined search patterns [15].…”

Section: Related Workmentioning

confidence: 99%

Collaborative online planning for automated victim search in disaster response

Beck

Teacy

Rogers

et al. 2018

Robotics and Autonomous Systems

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Collaboration is essential for effective performance by groups of robots in disaster response settings. Here we are particularly interested in heterogeneous robots that collaborate in complex scenarios with incomplete, dynamically changing information. In detail, we consider an automated victim search setting, where unmanned aerial vehicles (UAVs) with different capabilities work together to scan for mobile phones and find and provide information about possible victims near these phone locations. The state of the art for such collaboration is robot control based on independent planning for robots with different tasks and typically incorporates uncertainty with only a limited scope. In contrast, in this paper, we take into account complex relations between robots with different tasks. As a result, we create a joint, full-horizon plan for the whole robot team by optimising over the uncertainty of future information gain using an online planner with hindsight optimisation. This joint plan is also used for further optimisation of individual UAV paths based on the long-term plans of all robots. We evaluate our planner’s performance in a realistic simulation environment based on a real disaster and find that our approach finds victims 25% faster compared to current state-of-the-art approaches

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Section: Related Workmentioning

confidence: 99%

Collaborative online planning for automated victim search in disaster response

Beck

Teacy

Rogers

et al. 2018

Robotics and Autonomous Systems

View full text Add to dashboard Cite

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“…14 Moreover, UAVs can be utilised in situations where the mission is too difficult or too dangerous for human pilots such as monitor critical structures in natural disasters, search and rescue and monitor weather inside a storm. 15 The path planning algorithms utilise sensory, processing and actuator systems to generate paths in view of different kinematic, dynamic 16,17 and environmental 18,19 time-varying constraints. Once a path is generated through the path planning algorithm, a path following algorithm will generate the control parameters for the UAV to follow the generated path.…”

Section: Introductionmentioning

confidence: 99%

Comparison of A* and RRT in real–time 3D path planning of UAVs

Zammit

Kampen

2020

AIAA Scitech 2020 Forum

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Unmanned Aerial Vehicles (UAVs) are being integrated into a wide range of military, industrial and commercial applications. Such applications require faultless autonomous systems to coordinate, guide, navigate and control different UAVs of different sizes, designed for different purposes with different capabilities. In this regard, different path planning algorithms were developed to ensure that UAVs are supplied with collision-free path paramount to which are the A* and the RRT algorithms, a graph-based and a samplingbased algorithm respectively. Such algorithms shall ideally operate in real-time to furnish the UAV navigation system with real-time, valid, obstacle-free paths in view of changes in the environment or other external or user-defined restrictions. Owing this need, in this paper a real-time platform to assess the performance of the A* and RRT algorithm with an associated smoothing algorithm was developed and tested using 3, 3D obstacle environment with different complexities. The salient user-defined, system-defined and internal constants were independently considered and their effect on performance assessed. Results showed that the A* outperformed the RRT algorithm in both path length and computational time for all scenarios considered with difference increasing with scenario complexity. But, both algorithms can be utilised if the associated parameters are attentively chosen based on the scenario the UAV will operate as both algorithm reached a 100% success rate for all scenario at specific parameter assignments.

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“…Path planning is the process of automatically generating feasible and optimal 2D 2, 3 or 3D 4,5 paths to a predefined destination in view of weather, 7,8 sensory and model constraints 9, 10 and uncertainties. 11,12 Different path planning algorithm were proposed each with their strongholds and drawbacks.…”

Section: Introductionmentioning

confidence: 99%

Advancements for A* and RRT in 3D path planning of UAVs

Zammit

Kampen

2019

AIAA Scitech 2019 Forum

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Advancements in Unmanned Aerial Vehicles (UAVs) design, actuator and sensory systems and control are making such devices financially available to a wide spectrum of users with various demands and expectations. To mitigate with this ever increasing demand robust, efficient and application-specific path planning is important. This paper presents advancements over the A* and the smoothing algorithms presented in, 1 utilising the same test scenarios. Analysis of results in 1 showed a ripple in path length as the resolution changes for all scenarios considered and less than 0.1% path length improvements after certain amount of smoothing iterates. To attenuate the path length ripple, the A* ripple reduction algorithm was developed. Results show a reduction of more than 46% in terms of standard deviation with respect to the original A* algorithm without any increase in the mean path length for all scenarios. Secondly, the smoothing algorithm developed in 1 was improved to stop smoothing based on the rate of smoothing of previous iterates. Results show more than 10 multiple less path smoothing time maintaining a path length reduction especially for simple scenarios. These advancements further portray the discussed path planning algorithms as candidates to the realisation of online 3D UAV path planning.

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An Intelligent, Heuristic Path Planner for Multiple Agent Unmanned Air Systems

Cited by 7 publications

References 10 publications

Collaborative online planning for automated victim search in disaster response

Collaborative online planning for automated victim search in disaster response

Comparison of A* and RRT in real–time 3D path planning of UAVs

Advancements for A* and RRT in 3D path planning of UAVs

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