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Robot Motion Planning: Approaches and Research Issues
Robotics and Artificial Intelligence Laboratory Indian Institute of Information Technology, Allahabad Robot Motion Planning: Approaches and Research Issues Rahul Kala rkala.in 12th June, 2014
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Problem Solving in Mobile Robotics
Environment Data Collection Environment Understanding Localization Map building Sensor Fusion Planning Control Manipulation R. Tiwari, A. Shukla, R. Kala (2013) Intelligent Planning for Mobile Robotics:Algorithmic Approaches, IGI Global Publishers,Hershey, PA. Robot Motion Planning rkala.in
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Planning Abstration Strategic Planning Milestone Planning
Path Planning Obstacle Avoidance Control Abstration R. Tiwari, A. Shukla, R. Kala (2013) Intelligent Planning for Mobile Robotics:Algorithmic Approaches, IGI Global Publishers,Hershey, PA. Robot Motion Planning rkala.in
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Problem Definition Goal Start Robot Motion Planning rkala.in
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Objective Travel Time Travel Speed Travel Distance Fuel Economy
Passenger Comfort Clearance Smoothness Robot Motion Planning rkala.in
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Research Issues Large offline/online computation Holonomicity
Unstructured environment Sensing/control errors Single/limited obstacle/robot environments Congested environments Narrow Corridors Dynamic Environment A priori known environment Wide maps Trap-prone environments Human Assistance Robot Motion Planning rkala.in
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Artificial Potential Fields
Base Algorithms Algorithms Deliberative Graph Search Based A* Sampling Based PRM RRT Optimization Based Genetic Algorithm Reactive Fuzzy Logic Artificial Potential Fields Robot Motion Planning rkala.in
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Pros and Cons: Graph search based
Resolution Optimal Resolution Complete Cons Time Complexity Discrete states Discrete action sets Holonomicity* Research Dynamic A* (D*) Any theta A* ε optimal A* * Can be controlled with a different modeling. Not implemented in the codes given Robot Motion Planning rkala.in
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Pros and Cons: PRM Pros Probabilistically Optimal
Probabilistically Complete Reasonable Computation time Cons Narrow corridor problem Roadmap generation not for dynamic environments Holonomicity Research Lazy PRM Vision based PRM K-connectivity PRM PRM without cycles Obstacle based sampling Suited to non-holonomicity Robot Motion Planning rkala.in
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Pros and Cons: RRT Pros Probabilistically Complete
Near real time performance Cons Narrow corridor problem Not optimal Voronoi bias Practically not complete Research RRT-Connect Graph based Local trees Obstacle based sampling Exploration in partially known environments Robot Motion Planning rkala.in
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Pros and Cons: Genetic Algorithm
Probabilistically Complete Probabilistically Optimal Cons Narrow corridor problem Computationally Expensive Practically not complete Research Shorten Operator Variable Length Chromosome Multi-objective optimization Memetic Computation Lazy collision checker Robot Motion Planning rkala.in
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Pros and Cons: Reactive Methods
Real time Can accommodate uncertainties Cons Not optimal Not complete Trap prone Research Training methods Input modeling Heuristic decision making Robot Motion Planning rkala.in
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And some ‘hybrids’ Robot Motion Planning rkala.in
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A* and Fuzzy R. Kala, A. Shukla, R. Tiwari (2010) Fusion of probabilistic A* algorithm and fuzzy inference system for robotic path planning. Artificial Intelligence Review, 33(4): Robot Motion Planning rkala.in
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A ‘better’ Genetic Algorithm
Variable Length Individual Soft Mutation Hard Mutation Elite Insert Repair Shorten R. Kala, A. Shukla, R. Tiwari (2011) Robotic Path Planning using Evolutionary Momentum based Exploration. Journal of Experimental and Theoretical Artificial Intelligence, 23(4): Robot Motion Planning rkala.in
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Genetic Algorithm + Genetic Algorithm
R. Kala, A. Shukla, R. Tiwari (2010) Dynamic Environment Robot Path Planning using Hierarchical Evolutionary Algorithms. Cybernetics and Systems, 41(6): Robot Motion Planning rkala.in
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Multi Resolution Graph Representation
Hierarchical A* Multi Resolution Graph Representation R. Kala, A. Shukla, R. Tiwari (2011) Robotic path planning in static environment using hierarchical multi-neuron heuristic search and probability based fitness. Neurocomputing, 74(14-15): Robot Motion Planning rkala.in
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Hierarchical A* R. Kala, A. Shukla, R. Tiwari (2011) Robotic path planning in static environment using hierarchical multi-neuron heuristic search and probability based fitness. Neurocomputing, 74(14-15): Robot Motion Planning rkala.in
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2-layered Dynamic Programming
R. Kala, A. Shukla, R. Tiwari (2012) Robot Path Planning using Dynamic Programming with Accelerating Nodes. Paladyn Journal of Behavioural Robotics, 3(1): Robot Motion Planning rkala.in
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And all this extended to Multi-Robotics
Robot Motion Planning rkala.in
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A* + GA R. Kala (2013) Multi-Robot Motion Planning using Hybrid MNHS and Genetic Algorithms. Applied Artificial Intelligence, 27(3): Robot Motion Planning rkala.in
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Rapidly-exploring Random Graphs
R. Kala (2013) Rapidly-exploring Random Graphs: Motion Planning of Multiple Mobile Robots. Advanced Robotics, 27(14): Robot Motion Planning rkala.in
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Coordination using Local Optimization
R. Kala (2014) Coordination in Navigation of Multiple Mobile Robots. Cybernetics and Systems, 45(1): 1-24. Robot Motion Planning rkala.in
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Coordination using Local Optimization
R. Kala (2014) Coordination in Navigation of Multiple Mobile Robots. Cybernetics and Systems, 45(1): 1-24. Robot Motion Planning rkala.in
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Coordination using A* + Fuzzy
R. Kala (2014) Navigating Multiple Mobile Robots without Direct Communication. International Journal of Intelligent Systems, DOI: /int [Accepted, In Press]. Robot Motion Planning rkala.in
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Complex Mobile Navigation and Manipulation
Thank You Complex Mobile Navigation and Manipulation rkala.in gcnandi.co.nr
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