Modeling robot motion planning with uncertainty in a Bayesian framework leads to a computationally intractable stochastic control problem. We seek hypotheses that can justify a separate implementation of control, localization and planning. In the end, we reduce the stochastic control problem to path-planning in the extended space of poses x covariances; the transitions between states are modeled through the use of the Fisher information matrix. In this framework, we consider two problems: minimizing the execution time, and minimizing the final covariance, with an upper bound on the execution time. Two correct and complete algorithms are presented. The first is the direct extension of classical graph-search algorithms in the extended space. The second one is a back-projection algorithm: uncertainty constraints are propagated backward from the goal towards the start state. ©2008 IEEE.
A Bayesian framework for optimal motion planning with uncertainty / Andrea, Censi; Calisi, Daniele; DE LUCA, Alessandro; Oriolo, Giuseppe. - (2008), pp. 1798-1805. (Intervento presentato al convegno 2008 IEEE International Conference on Robotics and Automation, ICRA 2008 tenutosi a Pasadena, CA nel 19 May 2008 through 23 May 2008) [10.1109/robot.2008.4543469].
A Bayesian framework for optimal motion planning with uncertainty
CALISI, daniele;DE LUCA, Alessandro;ORIOLO, Giuseppe
2008
Abstract
Modeling robot motion planning with uncertainty in a Bayesian framework leads to a computationally intractable stochastic control problem. We seek hypotheses that can justify a separate implementation of control, localization and planning. In the end, we reduce the stochastic control problem to path-planning in the extended space of poses x covariances; the transitions between states are modeled through the use of the Fisher information matrix. In this framework, we consider two problems: minimizing the execution time, and minimizing the final covariance, with an upper bound on the execution time. Two correct and complete algorithms are presented. The first is the direct extension of classical graph-search algorithms in the extended space. The second one is a back-projection algorithm: uncertainty constraints are propagated backward from the goal towards the start state. ©2008 IEEE.| File | Dimensione | Formato | |
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