Rigid body pose estimation based on the Lagrange-d’Alembert principle
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- 作者:Maziar Izadia ; maziar@tamu.edu" class="auth_mail" title="E-mail the corresponding authorAuthor Vitae ; Amit K. Sanyalb ; 1 ; aksanyal@syr.edu" class="auth_mail" title="E-mail the corresponding authorAuthor Vitae
- 关键词:Pose estimation ; Variational estimator ; Lagrange&ndash ; d&rsquo ; Alembert principle ; Lie group variational integrator
- 刊名:Automatica
- 出版年:2016
- 出版时间:September 2016
- 年:2016
- 卷:71
- 期:Complete
- 页码:78-88
- 全文大小:826 K
文摘
Stable estimation of rigid body pose and velocities from noisy measurements, without any knowledge of the dynamics model, is treated using the Lagrange–d’Alembert principle from variational mechanics. With body-fixed vision and inertial sensor measurements, a Lagrangian is obtained as the difference between a kinetic energy-like term that is quadratic in velocity estimation error and the sum of two artificial potential functions; one obtained from a generalization of Wahba’s function for attitude estimation and another which is quadratic in the position estimate error. An additional dissipation term that is linear in the velocity estimation error is introduced, and the Lagrange–d’Alembert principle is applied to the Lagrangian with this dissipation. A Lyapunov analysis shows that the state estimation scheme so obtained provides stable asymptotic convergence of state estimates to actual states in the absence of measurement noise, with an almost global domain of attraction. This estimation scheme is discretized for computer implementation using discrete variational mechanics, as a first order Lie group variational integrator. The discrete estimation scheme can also estimate velocities from such onboard sensor measurements. Moreover, all states can be estimated during time periods when measurements of only two inertial vectors, the angular velocity vector, and one feature point position vector are available in body frame. In the presence of bounded measurement noise in the vector measurements, numerical simulations show that the estimated states converge to a bounded neighborhood of the true states.