Autonomous Vehicles

1. Autonomous Vehicles By: Rotha Aing

2. What makes a vehicleautonomous? • “Driverless” • Different from remote controlled • 3 D’s • Detection • Delivery • Data-Gathering

3. 3D’s • Detection – Reasoning • The surroundings and current conditions • Data-gathering – Search • From the information search knowledgebase for purposed actions • What to do next? • Delivery – Learning • View and record results of actions

4. Current Approaches • Fully Autonomous • Taxi-like cars • Autonomous in closed systems • Monorails • Assistance System • Environment Sensing • Distance Sensors • ABS

5. Solution Template • Sensors: Figure out obstacles around the vehicle • Navigation: How to get to the target location from the present location • Motion planning: Getting to the location, getting by any obstacles, following any rules • Control: Getting the vehicle itself to move

6. Current Issues • Technical • Sensors • Understanding the environment • Navigation • Know its current position and where it wants to go • Motion Planning • Navigation through traffic • Actuation • Operate the correct and needed features

7. Issues • Social Issues • Trusting the car • Getting on public roads • Getting people to go in • Liability Issues • Lost Jobs

8. What’s been solved? • Control • Navigation • Some issues of Sensory

9. Control • Drive-By-Wire • Sends messages to onboard computers • Physical ties are unlinked • In most current cars

10. Drive By Wire • When sensor/trigger is pressed, it sends message to the car to perform the tasks

11. DBW in Autonomous Vehicles • Replace the human driver • Activate the sensors/triggers • SciAutonics • Servomotors for each gear • Large servomotor with belt drive for steering

12. Navigation • Already available • Combination of: • GPS • Roadside database

13. Sensory • Major issue: • Lack of computing power • “More processors” • Half completed • RADAR • Laser Detection • Cameras

14. Sensory Information Issues • Factors of weather • Dust, rain, fog • Correctly Identifying an obstacle • Shadows vs. ditches • Shallow vs. deep • Speed of the vehicle and the speed data can be correctly received

15. Motion Planning • Most challenging • Collision Detection • Affected by: • Quality of Sensory information • Quality of Controls • Need for algorithm that can determine movements quickly but also the correct ones

16. “Road Map” • Decision Tree (Graph) • With points A and G • Fill in free spots (Configuration Space) • Try to link A to G • Configuration Space Algorithms • Sampling-based • Faster, less computing power • Combinatorial • More complete

17. Configuration Space

18. DARPA Challenge • Defense Advanced Research Projects Agency • 2004 Desert Course • 2005 Off-road, mountain terrain • 2007 Urban Challenge • Collision Avoidance • Obey traffic signs

19. Stanley • 2005 DARPA Challenge winner • Volkswagen Touareg modified with onboard computers

20. Stanley’s Sensory • 5 LIDAR lasers • 24 GHz RADAR • Stereo camera • Single-lens camera

22. Path Analysis • Built in RDDF (database of course) • Vehicle predominantly followed the RDDF data

23. Obstacle Detection • Machine Learning Approach • Accuracy value of data is based on how human’s perform • Slows down when a path can not be found quickly • Grid of either occupied, free, or unknown spots

25. Issues with mapping scheme • Errors in determining environment • 12.6% of areas determined as obstacle was not

26. Alice out of challenge

27. Personal Opinions • Good progress since the first challenge • Not until the 2007 challenge will we really know if a fully autonomous vehicle is possible in the near future • Other approaches more likely to be developed into mainstream before fully autonomous vehicles