Safety-Critical Control for Obstacle Avoidance between Polytopes with Control Barrier Functions
Obstacle avoidance between polytopes is a challenging topic for optimal control and optimization-based trajectory planning problems. Existing work either solves this problem through mixed-integer optimization, relying on simplification of system dynamics, or through model predictive control with dual variables using distance constraints, requiring long horizons for obstacle avoidance. In either case, the solution can only be applied as an offline planning algorithm. In this paper, we exploit the property that a smaller horizon is sufficient for obstacle avoidance by using discrete-time control barrier function (DCBF) constraints and we propose a novel optimization formulation with dual variables based on DCBFs to generate a collision-free dynamically-feasible trajectory. The proposed optimization formulation has lower computational complexity compared to existing work and can be used as a fast online algorithm for control and planning for general nonlinear dynamical systems. We validate our algorithm on different robot shapes using numerical simulations with a kinematic bicycle model, resulting in successful navigation through maze environments with polytopic obstacles.
Open-source code is available at the following GitHub repository: https://github.com/HybridRobotics/cbf.
Видео Safety-Critical Control for Obstacle Avoidance between Polytopes with Control Barrier Functions канала Hybrid Robotics
Open-source code is available at the following GitHub repository: https://github.com/HybridRobotics/cbf.
Видео Safety-Critical Control for Obstacle Avoidance between Polytopes with Control Barrier Functions канала Hybrid Robotics
Показать
Комментарии отсутствуют
Информация о видео
Другие видео канала
Safety-Critical Geometric Control for Systems on Manifolds
Rule-Based Safety-Critical Control Design using CBFs with Application to Autonomous Lane Change
400m dash - RL for Versatile, Dynamic, and Robust Bipedal Locomotion Control
Supplementary Walking Experiments - RL for Versatile, Dynamic, and Robust Bipedal Locomotion Control
Optimal Robust Safety-Critical Control for Dynamic Robotics
Hierarchical Reinforcement Learning for Precise Soccer Shooting Skills using a Quadrupedal Robot
Dynamic Legged Manipulation of a Ball through Multi-Contact Optimization
Dynamic Walking on Stepping Stones with Gait Library and Control Barrier Functions
Gaussian Process-based Min-norm Stabilizing Controller for Control-Affine Systems with Uncertainty
Deep Visual Perception for Dynamic Walking on Discrete Terrain
Supplementary Running Experiments - RL for Versatile, Dynamic, and Robust Bipedal Locomotion Control
Dynamic Walking on Randomly-Varying Discrete Terrain with One-step Preview
Dynamic Walking on Randomly-Varying Discrete Terrain with One-step Preview
Competitive Car Racing with Multiple Vehicles
Reinforcement Learning for Versatile, Dynamic, and Robust Bipedal Locomotion Control
Safe Teleoperation of Dynamic UAVs through Control Barrier Functions
Geometric L1 Adaptive Attitude Control for Quadrotor UAV
Motion Planning and Feedback Control for Bipedal Robots riding a Snakeboard
3D Dynamic Walking on Stepping Stones with Control Barrier Functions
Robust and Versatile Bipedal Jumping Control through Multi-Task Reinforcement Learning
Differential Flatness based Direct Collocation for a Quadrotor with a Cable-Suspended Payload