On-Road Intelligent Vehicles Motion Planning for Intelligent Transportation Systems
Auteur : Kala Rahul
On-Road Intelligent Vehicles: Motion Planning for Intelligent Transportation Systems deals with the technology of autonomous vehicles, with a special focus on the navigation and planning aspects, presenting the information in three parts. Part One deals with the use of different sensors to perceive the environment, thereafter mapping the multi-domain senses to make a map of the operational scenario, including topics such as proximity sensors which give distances to obstacles, vision cameras, and computer vision techniques that may be used to pre-process the image, extract relevant features, and use classification techniques like neural networks and support vector machines for the identification of roads, lanes, vehicles, obstacles, traffic lights, signs, and pedestrians.
With a detailed insight into the technology behind the vehicle, Part Two of the book focuses on the problem of motion planning. Numerous planning techniques are discussed and adapted to work for multi-vehicle traffic scenarios, including the use of sampling based approaches comprised of Genetic Algorithm and Rapidly-exploring Random Trees and Graph search based approaches, including a hierarchical decomposition of the algorithm and heuristic selection of nodes for limited exploration, Reactive Planning based approaches, including Fuzzy based planning, Potential Field based planning, and Elastic Strip and logic based planning.
Part Three of the book covers the macroscopic concepts related to Intelligent Transportation Systems with a discussion of various topics and concepts related to transportation systems, including a description of traffic flow, the basic theory behind transportation systems, and generation of shock waves.
Part I: Autonomous Vehicles
1. Introduction
2. Basics of Autonomous Vehicles
3. Perception in Autonomous Vehicles
4. Advanced Driver Assistance Systems
Part II: Deliberative Motion Planning of Autonomous Vehicles
5. Introduction to Planning
6. Optimization Based Planning
7. Sampling Based Planning
8. Graph Search based Hierarchical Planning
9. Using Heuristics in Graph Search based Planning
Part III: (Near-)Reactive Motion Planning of Autonomous Vehicles
10. Fuzzy Based Planning
11. Potential Based Planning
12. Logic Based Planning
Part IV: Intelligent Transportation Systems
13. Basics of Intelligent Transportation System
14. Intelligent Transportation Systems with Diverse Vehicles
15. Reaching Destination before Deadline with Intelligent Transportation Systems
16. Conclusions
Appendix A: Resources from the Author
- Provides an overall coverage of autonomous vehicles and Intelligent Transportation Systems
- Presents a detailed overview, followed by the challenging problems of navigation and planning
- Teaches how to compare, contrast, and differentiate navigation algorithms
Date de parution : 04-2016
Ouvrage de 536 p.
15x22.8 cm
Thèmes d’On-Road Intelligent Vehicles :
Mots-clés :
A Adaptive cruise control; Advanced Driver Assistance Systems; algorithm; Artificial potential fields; Automatic parking; Autonomous vehicles; Configuration space; Congesting avoidance; Control; Cooperative intelligent transportation systems; Cooperative overtaking; Decentralized motion planning; Discrete logic; Elastic strip; Evolutionary computation; Evolutionary robotics; Fatigue alert systems; Fuzzy controllers; Fuzzy interference system; Fuzzy logic; Genetic algorithms; Graph search; Hierarchical planning; Intelligent driver model; Intelligent transportation systems; Intelligent vehicles; Intersection management; Inter-vehicle communication; Lane tracking; Localization; Logic programming; Logic-based planning; Microscopic traffic simulation; Mobile robotics; Motion planning; Multilayered planning; Multirobot coordination; Obstacle avoidance; Obstacle detection; Optimization; Overtaking assist; Overtaking; Planning; Rapidly exploring random trees connect; Rapidly exploring random trees; Replanning; Road detection; Roadmap; Robot motion planning; Routing; Sampling-based robotics; Searching; Semiautonomous vehicles; Sensing; Sensor fusion; Sensors; Start time computation; Traffic light management; Traffic merging; Traffic simulation; Traffic-flow theory; Uniform cost search; Unorganized traffic; Vehicle behaviours; Vehicle overtaking; Vehicle planning; Vehicle routing; Vehicle-following model; Vision