论文信息 - PRACSYS: An Extensible Architecture for Composing Motion Controllers and Planners

PRACSYS: An Extensible Architecture for Composing Motion Controllers and Planners

This paper describes a software infrastructure for developing controllers and planners for robotic systems, referred here as PRACSYS . At the core of the software is the abstraction of a dynamical system, which, given a control, propagates its state forward in time. The platform simplifies the development of new controllers and planners and provides an extensible framework that allows complex interactions between one or many controllers, as well as motion planners. For instance, it is possible to compose many control layers over a physical system, to define multi-agent controllers that operate over many systems, to easily switch between different underlying controllers, and plan over controllers to achieve feedback-based planning. Such capabilities are especially useful for the control of hybrid and cyber-physical systems, which are important in many applications. The software is complementary and builds on top of many existing open-source contributions. It allows the use of different libraries as plugins for various modules, such as collision checking, physics-based simulation, visualization, and planning. This paper describes the overall architecture, explains important features and provides use-cases that evaluate aspects of the infrastructure.

[1] KangKang Yin,et al. SIMBICON: simple biped locomotion control , 2007, ACM Trans. Graph..

[2] Dinesh Manocha,et al. OBBTree: a hierarchical structure for rapid interference detection , 1996, SIGGRAPH.

[3] Olivier Michel,et al. Cyberbotics Ltd. Webots™: Professional Mobile Robot Simulation , 2004 .

[4] Richard T. Vaughan,et al. The Player/Stage Project: Tools for Multi-Robot and Distributed Sensor Systems , 2003 .

[5] James J. Kuffner,et al. OpenRAVE: A Planning Architecture for Autonomous Robotics , 2008 .

[6] Olivier Michel,et al. Cyberbotics Ltd. Webots™: Professional Mobile Robot Simulation , 2004, ArXiv.

[7] Paolo Fiorini,et al. Motion Planning in Dynamic Environments Using Velocity Obstacles , 1998, Int. J. Robotics Res..

[8] Huy L. Nguyen. Approximate Nearest Neighbor Search in ℓp , 2013, ArXiv.

[9] Peter K. Allen,et al. Graspit! A versatile simulator for robotic grasping , 2004, IEEE Robotics & Automation Magazine.

[10] John W. Eaton,et al. Gnu Octave Manual , 2002 .

[11] Sunil Arya,et al. Approximate nearest neighbor queries in fixed dimensions , 1993, SODA '93.

[12] Russ Tedrake,et al. Simulation-based LQR-trees with input and state constraints , 2010, 2010 IEEE International Conference on Robotics and Automation.

[13] Stefano Carpin,et al. USARSim: a robot simulator for research and education , 2007, Proceedings 2007 IEEE International Conference on Robotics and Automation.