Dynamic Path Planning for Unmanned Vehicles Based on Fuzzy Logic and Improved Ant Colony Optimization

Song, Qi; Zhao, Qinglei; Wang, Shuxin; Liu, Qiang; Chen, Xiaohe

doi:10.1109/access.2020.2984695

Cited by 81 publications

(44 citation statements)

References 23 publications

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“…First, it would be interesting to investigate if the application of the pseudo-random action choice rule [20] could improve the MS-MMAS results. Another further promising idea is the use of pheromone update rule based on ants ranking [25]. Extension of the MS-MMAS implementation design with parallel computing techniques [10] and hybridization with other meta-heuristics [26][27][28] is other interesting opportunity for the future research.…”

Section: Discussionmentioning

confidence: 99%

Multi-Strategy MAX-MIN Ant System for Solving Quota Traveling Salesman Problem with Passengers, Incomplete Ride and Collection Time

Silva¹,

Fernandes²,

Goldbarg³

et al. 2021

Operations Management - Emerging Trend in the Digital Era

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This study proposes a novel adaptation of MAX-MIN Ant System algorithm for the Quota Traveling Salesman Problem with Passengers, Incomplete Ride, and Collection Time. There are different types of decisions to solve this problem: satisfaction of the minimum quota, acceptance of ride requests, and minimization of travel costs under the viewpoint of the salesman. The Algorithmic components proposed regards vehicle capacity, travel time, passenger limitations, and a penalty for delivering a passenger deliverance out of the required destination. The antbased algorithm incorporates different sources of heuristic information for the ants and memory-based principles. Computational results are reported, showing the effectiveness of this ant-based algorithm.

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Section: Discussionmentioning

confidence: 99%

Multi-Strategy MAX-MIN Ant System for Solving Quota Traveling Salesman Problem with Passengers, Incomplete Ride and Collection Time

Silva¹,

Fernandes²,

Goldbarg³

et al. 2021

Operations Management - Emerging Trend in the Digital Era

View full text Add to dashboard Cite

show abstract

“…In this sense, Artificial Intelligence (AI) techniques such as Fuzzy Logic (FL), Neural Networks (NNs) and meta-heuristics are recurrently found in the specialized literature. In [19], the Ant Colony Optimization (ACO) algorithm improved with FL is used to obtain cost-effective paths with an unmanned aerial vehicle in dynamic environments. Another example is the work in [20], where a NN is used to dynamically predict and avoid collisions in the path-planning for mobile robots.…”

Section: Introduction 1a Review Of Path-planning Methodsmentioning

confidence: 99%

Path-Planning for Mobile Robots Using a Novel Variable-Length Differential Evolution Variant

et al. 2021

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Mobile robots are currently exploited in various applications to enhance efficiency and reduce risks in hard activities for humans. The high autonomy in those systems is strongly related to the path-planning task. The path-planning problem is complex and requires in its formulation the adjustment of path elements that take the mobile robot from a start point to a target one at the lowest cost. Nevertheless, the identity or the number of the path elements to be adjusted is unknown; therefore, the human decision is necessary to determine this information reducing autonomy. Due to the above, this work conceives the path-planning as a Variable-Length-Vector optimization problem (VLV-OP) where both the number of variables (path elements) and their values must be determined. For this, a novel variant of Differential Evolution for Variable-Length-Vector optimization named VLV-DE is proposed to handle the path-planning VLV-OP for mobile robots. VLV-DE uses a population with solution vectors of different sizes adapted through a normalization procedure to allow interactions and determine the alternatives that better fit the problem. The effectiveness of this proposal is shown through the solution of the path-planning problem in complex scenarios. The results are contrasted with the well-known A* and the RRT*-Smart path-planning methods.

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“…Virtual map and the real map Accelerated convergence speed [12] Dynamic Fuzzy logic based path planning Wireless sensor networks in MATLAB Localization ratio and localization accuracy [13] Dynamic fuzzy-logic-ant colony system Regions of London, United Kingdom Efficient route selection [14] Ant colony and fuzzy logic Simulated maps in MATLAB Shortest path in minimum time [15] Fuzzy logic ant colony optimization Simulated road networks Shortest path length [16] Cuckoo optimization algorithm Simulated scenarios of size 20 × 20, 100 × 100 and 200 × 200 Safe, smooth, and collision-free path [17] A visual-inertial navigation system Urban areas of Hong Kong Effective mitigation of dynamic objects and improved accuracy [18] Fuzzy-genetic algorithm (GA) with three path concept Simulated maps Computationally efficient [19] Improved gravitational search Real-time navigation using Khepera III mobile robot The safe and shortest path [20] Genetic Zhang et al [25] made an extensive survey on path planning approaches for mobile robots. In their work, they emphasized the advantages of using a genetic algorithm, particle swarm optimization, ant colony optimization, and artificial potential fields in path planning with future directions.…”

Section: Ref #mentioning

confidence: 99%

“…In this stage, the pheromone update rule is used to find the current pheromone quantity. The intensity of pheromone is updated using (15). The usability of the path is either increased by pheromone reinforcement, or decreased through pheromone evaporation.…”

Section: Path Selectionmentioning

confidence: 99%

A Fuzzy Gain-Based Dynamic Ant Colony Optimization for Path Planning in Dynamic Environments

et al. 2021

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Path planning can be perceived as a combination of searching and executing the optimal path between the start and destination locations. Deliberative planning capabilities are essential for the motion of autonomous unmanned vehicles in real-world scenarios. There is a challenge in handling the uncertainty concerning the obstacles in a dynamic scenario, thus requiring an intelligent, robust algorithm, with the minimum computational overhead. In this work, a fuzzy gain-based dynamic ant colony optimization (FGDACO) for dynamic path planning is proposed to effectively plan collision-free and smooth paths, with feasible path length and the minimum time. The ant colony system’s pheromone update mechanism was enhanced with a sigmoid gain function for effective exploitation during path planning. Collision avoidance was achieved through the proposed fuzzy logic control. The results were validated using occupancy grids of variable size, and the results were compared against existing methods concerning performance metrics, namely, time and length. The consistency of the algorithm was also analyzed, and the results were statistically verified.

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Dynamic Path Planning for Unmanned Vehicles Based on Fuzzy Logic and Improved Ant Colony Optimization

Cited by 81 publications

References 23 publications

Multi-Strategy MAX-MIN Ant System for Solving Quota Traveling Salesman Problem with Passengers, Incomplete Ride and Collection Time

Multi-Strategy MAX-MIN Ant System for Solving Quota Traveling Salesman Problem with Passengers, Incomplete Ride and Collection Time

Path-Planning for Mobile Robots Using a Novel Variable-Length Differential Evolution Variant

A Fuzzy Gain-Based Dynamic Ant Colony Optimization for Path Planning in Dynamic Environments

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