Path/Action Planning for a Mobile Robot
This thesis consists of two parts united by the theme of path/action planning for a mobile robot. Part I presents the Second Opinion Planner (SOP), and Part II presents a new paradigm for navigating, growing, and planning on a Network of Reusable Paths (NRP). Path/action planning is common to both p...
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| Other Authors: | , |
| Format: | Thesis |
| Language: | English |
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| Online Access: | http://hdl.handle.net/1807/36006 |
| _version_ | 1821498533409193984 |
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| author | Stenning, Braden Edward |
| author2 | Barfoot, Timothy D. Aerospace Science and Engineering |
| author_facet | Stenning, Braden Edward |
| author_sort | Stenning, Braden Edward |
| collection | University of Toronto: Research Repository T-Space |
| description | This thesis consists of two parts united by the theme of path/action planning for a mobile robot. Part I presents the Second Opinion Planner (SOP), and Part II presents a new paradigm for navigating, growing, and planning on a Network of Reusable Paths (NRP). Path/action planning is common to both parts in that the planning algorithm must choose the terrain assessment or localization technique at the path-planning stage. Terrain-assessment algorithms follow the trend of low-fidelity at low-cost and high-fidelity at high-cost. Using a high-fidelity method on all the raw terrain data can drastically increase a robot's total path cost (cost of driving, planning, and doing the terrain assessment). SOP is a path-planning algorithm that uses a hierarchy of terrain-assessment methods, from low-fidelity to high-fidelity, and seeks to limit high-cost assessment to areas where it is beneficial. The decision to assess some terrain with a higher-fidelity method is made considering potential path benefits and the cost of assessment. SOP provides a means to triage large amounts of terrain data. The system is demonstrated on simulated problems and in real terrain from an experimental field test carried out on Devon Island, Canada. The SOP plans are quite close to the minimum possible cost. Growing a NRP is an approach to navigation that allows a mobile robot to autonomously explore unmapped, GPS-denied environments. This new paradigm results in closer goal acquisition and a more robust approach to exploration with a mobile robot, when compared to a classic approach to guidance, navigation, and control. A NRP is a simple Simultaneous Localization And Mapping system that can be shown to be a physical embodiment of a Rapidly-exploring Random Tree planner. Simulation results are presented, as well as the results from two different robotic test systems that were tested in planetary analogue environments. NRP offers benefits to planetary exploration by allowing a rover to be used for the parallel scientific investigations. This increases the number of sites that can be investigated in a short time, as compared to a serial approach to exploration. Two mock missions were carried out at planetary analogue sites. PhD |
| format | Thesis |
| genre | Devon Island |
| genre_facet | Devon Island |
| geographic | Canada Devon Island |
| geographic_facet | Canada Devon Island |
| id | ftunivtoronto:oai:localhost:1807/36006 |
| institution | Open Polar |
| language | English |
| long_lat | ENVELOPE(-88.000,-88.000,75.252,75.252) |
| op_collection_id | ftunivtoronto |
| op_relation | http://hdl.handle.net/1807/36006 |
| publishDate | |
| record_format | openpolar |
| spelling | ftunivtoronto:oai:localhost:1807/36006 2025-01-16T21:37:40+00:00 Path/Action Planning for a Mobile Robot Stenning, Braden Edward Barfoot, Timothy D. Aerospace Science and Engineering NO_RESTRICTION http://hdl.handle.net/1807/36006 en_ca eng http://hdl.handle.net/1807/36006 mobile robot autonomy field robotics path planning 0538 Robotics Thesis ftunivtoronto 2020-06-17T11:23:31Z This thesis consists of two parts united by the theme of path/action planning for a mobile robot. Part I presents the Second Opinion Planner (SOP), and Part II presents a new paradigm for navigating, growing, and planning on a Network of Reusable Paths (NRP). Path/action planning is common to both parts in that the planning algorithm must choose the terrain assessment or localization technique at the path-planning stage. Terrain-assessment algorithms follow the trend of low-fidelity at low-cost and high-fidelity at high-cost. Using a high-fidelity method on all the raw terrain data can drastically increase a robot's total path cost (cost of driving, planning, and doing the terrain assessment). SOP is a path-planning algorithm that uses a hierarchy of terrain-assessment methods, from low-fidelity to high-fidelity, and seeks to limit high-cost assessment to areas where it is beneficial. The decision to assess some terrain with a higher-fidelity method is made considering potential path benefits and the cost of assessment. SOP provides a means to triage large amounts of terrain data. The system is demonstrated on simulated problems and in real terrain from an experimental field test carried out on Devon Island, Canada. The SOP plans are quite close to the minimum possible cost. Growing a NRP is an approach to navigation that allows a mobile robot to autonomously explore unmapped, GPS-denied environments. This new paradigm results in closer goal acquisition and a more robust approach to exploration with a mobile robot, when compared to a classic approach to guidance, navigation, and control. A NRP is a simple Simultaneous Localization And Mapping system that can be shown to be a physical embodiment of a Rapidly-exploring Random Tree planner. Simulation results are presented, as well as the results from two different robotic test systems that were tested in planetary analogue environments. NRP offers benefits to planetary exploration by allowing a rover to be used for the parallel scientific investigations. This increases the number of sites that can be investigated in a short time, as compared to a serial approach to exploration. Two mock missions were carried out at planetary analogue sites. PhD Thesis Devon Island University of Toronto: Research Repository T-Space Canada Devon Island ENVELOPE(-88.000,-88.000,75.252,75.252) |
| spellingShingle | mobile robot autonomy field robotics path planning 0538 Robotics Stenning, Braden Edward Path/Action Planning for a Mobile Robot |
| title | Path/Action Planning for a Mobile Robot |
| title_full | Path/Action Planning for a Mobile Robot |
| title_fullStr | Path/Action Planning for a Mobile Robot |
| title_full_unstemmed | Path/Action Planning for a Mobile Robot |
| title_short | Path/Action Planning for a Mobile Robot |
| title_sort | path/action planning for a mobile robot |
| topic | mobile robot autonomy field robotics path planning 0538 Robotics |
| topic_facet | mobile robot autonomy field robotics path planning 0538 Robotics |
| url | http://hdl.handle.net/1807/36006 |