Presentation is loading. Please wait.

Presentation is loading. Please wait.

EE631 Cooperating Autonomous Mobile Robots Lecture 5: Collision Avoidance in Dynamic Environments Prof. Yi Guo ECE Dept.

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "EE631 Cooperating Autonomous Mobile Robots Lecture 5: Collision Avoidance in Dynamic Environments Prof. Yi Guo ECE Dept."— Presentation transcript:

1 EE631 Cooperating Autonomous Mobile Robots Lecture 5: Collision Avoidance in Dynamic Environments Prof. Yi Guo ECE Dept.

2 Plan A Collision Avoidance Algorithm A Global Motion Planning Scheme

3 Nonholonomic Kinematic Model Coordinate transformation and input mapping ( ,  are within (-  /2,  /2)): Chained form (after transformation):

4 Assumptions: The Robot 2-dimensional circle with radius R Knowing its start and goal positions Onboard sensors detecting dynamic obstacles

5 Assumptions: The Environment 2D environment with static and dynamic obstacles Pre-defined map with static obstacle locations known Dynamic obstacles represented by circles with radius r i

6 Problem Formulation: Trajectory Planning Find feasible trajectories for the robot, enrouting from its start position to its goal, without collisions with static and dynamic obstacles.

7 Feasible Trajectory in Free Space A family of feasible trajectories: Boundary conditions  In original coordinate:  In transformed coordinate:

8 Parameterized Feasible Trajectory Imposing boundary conditions, parameterization of the trajectory in terms of a 6 :  A, B, Y are constant matrices calculated from boundary conditions  a 6 increases the freedom of maneuver accounting for geometric constrains posed by dynamic obstacles

9

10 Steering Paradigm Polynomial steering: Assume T is the time that takes the robot to get to q f from q 0. Choose then

11 A quick summary System model: chained form Feasible trajectories: closed form parameterization Steering control: closed form, piecewise constant solution (polynomial steering) Next: Collision avoidance -- explicit condition based on geometry and time

12 Dynamic Collision Avoidance Criteria Time + space collision

13 Dynamic Collision Avoidance Criteria Time criterion:  Assume obstacle moves at constant velocity during sampling period  In original coordinate:  In transformed coordinate :

14 Dynamic Collision Avoidance Criteria Geometry criterion:  In original coordinate:  In transformed coordinate: Mapping from x-y plane to z 1 -z 4 plane indicates collision region within a circle of radius r i +R+l/2, since

15 Dynamic Collision Avoidance Criteria Time criterion + geometrical criterion + path parameterization  g 2, g 1i, g 0i are analytic functions of their arguments and can be calculated real time  a 6 k exists if g 2 >0  g 2 >0 holds for every points except boundary points

16 Global Path Planning Using D* Search A shortest path returned by D* in 2D environment Robot path Static obstacles Start Goal

17 Global Motion Planning Algorithm flow chart

18 Simulations In 2D environment with static obstacles ( In 2D environment with static obstacles (a 6 =0) Static obstacles Feasible trajectory Start Goal

19 Collision Trajectory – Circles are drawn with 5 second spacing – Onboard sensors detect:  obstacle 1: center [23,15], velocity [0.1,0.2]  obstacle 2: center [45,20], velocity [-0.1,-0.1] – Collisions occurs Robot Moving obstacles Static obstacles

20 Global Collision–Free Trajectory a 6 1 =9.4086*10 -6, a 6 2 =4.9973*10 -6 Robot Moving obstacles Static obstacles

21 Global Collision–Free Trajectory  Moving obstacle changes velocity: Original velocity [-0.15,-0.1], new velocity [0.15,-0.29]  Calculated a 6 2 =9.4086*10 -6, a 6 2 =4.9973*10 -6 Robot Moving obstacles Static obstacles

22 Readings: Laumond book Chapter 1 “A new analytical solution to mobile robot trajectory generation in the presence of moving obstacles”, by Zhihua Qu, Jing Wang, Plaisted, C.E., IEEE Transactions on Robotics, Volume 20, Issue 6, Dec. 2004 Page(s):978 - 993

Download ppt "EE631 Cooperating Autonomous Mobile Robots Lecture 5: Collision Avoidance in Dynamic Environments Prof. Yi Guo ECE Dept."

Similar presentations

TECHNOLOGICAL INSTITUTE Center for Robot Technology.

TECHNOLOGICAL INSTITUTE Center for Robot Technology.
Motion Planning for Point Robots CS 659 Kris Hauser.

Motion Planning for Point Robots CS 659 Kris Hauser.
Feasible trajectories for mobile robots with kinematic and environment constraints Paper by Jean-Paul Laumond I am Henrik Tidefelt.

Feasible trajectories for mobile robots with kinematic and environment constraints Paper by Jean-Paul Laumond I am Henrik Tidefelt.
CIS 540 Principles of Embedded Computation Spring 2015 Instructor: Rajeev Alur

CIS 540 Principles of Embedded Computation Spring Instructor: Rajeev Alur
The Vector Field Histogram Erick Tryzelaar November 14, 2001 Robotic Motion Planning A Method Developed by J. Borenstein and Y. Koren.

The Vector Field Histogram Erick Tryzelaar November 14, 2001 Robotic Motion Planning A Method Developed by J. Borenstein and Y. Koren.
Generated Waypoint Efficiency: The efficiency considered here is defined as follows: As can be seen from the graph, for the obstruction radius values (200,

Generated Waypoint Efficiency: The efficiency considered here is defined as follows: As can be seen from the graph, for the obstruction radius values (200,
INTRODUCTION TO DYNAMICS ANALYSIS OF ROBOTS (Part 6)

INTRODUCTION TO DYNAMICS ANALYSIS OF ROBOTS (Part 6)
Kinodynamic Path Planning Aisha Walcott, Nathan Ickes, Stanislav Funiak October 31, 2001.

Kinodynamic Path Planning Aisha Walcott, Nathan Ickes, Stanislav Funiak October 31, 2001.
NUS CS5247 Randomized Kinodynamic Motion Planning with Moving Obstacles - D. Hsu, R. Kindel, J.C. Latombe, and S. Rock. Int. J. Robotics Research, 21(3):233-255,

NUS CS5247 Randomized Kinodynamic Motion Planning with Moving Obstacles - D. Hsu, R. Kindel, J.C. Latombe, and S. Rock. Int. J. Robotics Research, 21(3): ,
Randomized Kinodynamics Motion Planning with Moving Obstacles David Hsu, Robert Kindel, Jean-Claude Latombe, Stephen Rock.

Randomized Kinodynamics Motion Planning with Moving Obstacles David Hsu, Robert Kindel, Jean-Claude Latombe, Stephen Rock.
Jur van den Berg, Stephen J. Guy, Ming Lin, Dinesh Manocha University of North Carolina at Chapel Hill Optimal Reciprocal Collision Avoidance (ORCA)

Jur van den Berg, Stephen J. Guy, Ming Lin, Dinesh Manocha University of North Carolina at Chapel Hill Optimal Reciprocal Collision Avoidance (ORCA)
Multi-Robot Motion Planning Jur van den Berg. Outline Recap: Configuration Space for Single Robot Multiple Robots: Problem Definition Multiple Robots:

Multi-Robot Motion Planning Jur van den Berg. Outline Recap: Configuration Space for Single Robot Multiple Robots: Problem Definition Multiple Robots:
Motion Planning of Multi-Limbed Robots Subject to Equilibrium Constraints. Timothy Bretl Presented by Patrick Mihelich and Salik Syed.

Motion Planning of Multi-Limbed Robots Subject to Equilibrium Constraints. Timothy Bretl Presented by Patrick Mihelich and Salik Syed.
CS 326 A: Motion Planning Coordination of Multiple Robots.

CS 326 A: Motion Planning Coordination of Multiple Robots.
Trajectory Week 8. Learning Outcomes By the end of week 8 session, students will trajectory of industrial robots.

Trajectory Week 8. Learning Outcomes By the end of week 8 session, students will trajectory of industrial robots.
Self-Collision Detection and Prevention for Humonoid Robots Paper by James Kuffner et al. Presented by David Camarillo.

Self-Collision Detection and Prevention for Humonoid Robots Paper by James Kuffner et al. Presented by David Camarillo.
CS 326A: Motion Planning Non-Holonomic Motion Planning.

CS 326A: Motion Planning Non-Holonomic Motion Planning.
CS 326 A: Motion Planning 2 Dynamic Constraints and Optimal Planning.

CS 326 A: Motion Planning 2 Dynamic Constraints and Optimal Planning.
1 University of Freiburg Computer Networks and Telematics Prof. Christian Schindelhauer Mobile Ad Hoc Networks Mobility (II) 11th Week 04.07.-06.07.2007.

1 University of Freiburg Computer Networks and Telematics Prof. Christian Schindelhauer Mobile Ad Hoc Networks Mobility (II) 11th Week
BINARY MORPHOLOGY and APPLICATIONS IN ROBOTICS. Applications of Minkowski Sum 1.Minkowski addition plays a central role in mathematical morphology 2.It.

BINARY MORPHOLOGY and APPLICATIONS IN ROBOTICS. Applications of Minkowski Sum 1.Minkowski addition plays a central role in mathematical morphology 2.It.

Similar presentations

Ads by Google