Some properties of the Riemannian distance function and the position vector X, with applications to the construction of Lyapunov functions

Pait, Felipe; Colón, Diego

doi:10.1109/cdc.2010.5717398

Cited by 9 publications

(6 citation statements)

References 4 publications

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“…where

is a vector field composed of the initial velocities of all geodesics departing from the origin

, and

is the inner product (3). As proved by Pait and Colon (2010) , the function (42) is a Lyapunov function for a dynamical system

such that

if the Lie derivative

is negative everywhere except at the origin

. To verify this condition, we first express the velocity of the dynamical system (41) in the tangent space of

using parallel transport as…”

Section: Tracking Manipulability Ellipsoidsmentioning

confidence: 99%

Geometry-aware manipulability learning, tracking, and transfer

Jaquier

Rozo

Calinon

2020

The International Journal of Robotics Research

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Body posture influences human and robot performance in manipulation tasks, as appropriate poses facilitate motion or the exertion of force along different axes. In robotics, manipulability ellipsoids arise as a powerful descriptor to analyze, control, and design the robot dexterity as a function of the articulatory joint configuration. This descriptor can be designed according to different task requirements, such as tracking a desired position or applying a specific force. In this context, this article presents a novel manipulability transfer framework, a method that allows robots to learn and reproduce manipulability ellipsoids from expert demonstrations. The proposed learning scheme is built on a tensor-based formulation of a Gaussian mixture model that takes into account that manipulability ellipsoids lie on the manifold of symmetric positive-definite matrices. Learning is coupled with a geometry-aware tracking controller allowing robots to follow a desired profile of manipulability ellipsoids. Extensive evaluations in simulation with redundant manipulators, a robotic hand and humanoids agents, as well as an experiment with two real dual-arm systems validate the feasibility of the approach.

show abstract

“…where

is a vector field composed of the initial velocities of all geodesics departing from the origin

, and

is the inner product (3). As proved by Pait and Colon (2010) , the function (42) is a Lyapunov function for a dynamical system

such that

if the Lie derivative

is negative everywhere except at the origin

. To verify this condition, we first express the velocity of the dynamical system (41) in the tangent space of

using parallel transport as…”

Section: Tracking Manipulability Ellipsoidsmentioning

confidence: 99%

Geometry-aware manipulability learning, tracking, and transfer

Jaquier

Rozo

Calinon

2020

The International Journal of Robotics Research

View full text Add to dashboard Cite

show abstract

“…where F = Log M (M ) is a vector field composed of the initial velocities of all geodesics departing from the origin M , and •, • M is the inner product (3). As proved in [Pait and Colón (2010)], the function ( 42) is a Lyapunov function for a dynamical system Ṁ = h(M ) such that h( M ) = 0 if the Lie derivative L h V (M ) = 2 h, F M is negative everywhere except at the origin M . To verify this condition, we first express the velocity of the dynamical system (41) in the tangent space of M using parallel transport as…”

Section: Stability Analysismentioning

confidence: 99%

Geometry-aware Manipulability Learning, Tracking and Transfer

Jaquier¹,

Rozo²,

Caldwell³

et al. 2018

Preprint

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Body posture influences human and robots performance in manipulation tasks, as appropriate poses facilitate motion or force exertion along different axes. In robotics, manipulability ellipsoids arise as a powerful descriptor to analyze, control and design the robot dexterity as a function of the articulatory joint configuration. This descriptor can be designed according to different task requirements, such as tracking a desired position or apply a specific force. In this context, this paper presents a novel manipulability transfer framework, a method that allows robots to learn and reproduce manipulability ellipsoids from expert demonstrations. The proposed learning scheme is built on a tensorbased formulation of a Gaussian mixture model that takes into account that manipulability ellipsoids lie on the manifold of symmetric positive definite matrices. Learning is coupled with a geometry-aware tracking controller allowing robots to follow a desired profile of manipulability ellipsoids. Extensive evaluations in simulation with redundant manipulators, a robotic hand and humanoids agents, as well as an experiment with two real dual-arm systems validate the feasibility of the approach.

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“…The following theorem gives the existence of Lyapunov functions and also characterizes their properties for locally asymptotically stable systems evolving on Riemannian manifolds in normal neighborhoods of equilibriums of dynamical systems. In [30,35] the Riemannian distance function is employed as a candidate to construct Lyapunov functions for dynamical systems on Riemannian manifolds. For general discussions on the construction of Lyapunov functions on Riemannian manifolds and metric spaces see [6,7,13,28,30,35].…”

Section: Remark 2 Theorem 3 Characterizes the Local Behavior Of State...mentioning

confidence: 99%

“…In [30,35] the Riemannian distance function is employed as a candidate to construct Lyapunov functions for dynamical systems on Riemannian manifolds. For general discussions on the construction of Lyapunov functions on Riemannian manifolds and metric spaces see [6,7,13,28,30,35].…”

Section: Remark 2 Theorem 3 Characterizes the Local Behavior Of State...mentioning

confidence: 99%

A Local Characterization of Lyapunov Functions and Robust Stability of Perturbed Systems on Riemannian Manifolds

Taringoo,

Dower,

Nešić

et al. 2013

Preprint

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This paper proposes converse Lyapunov theorems for nonlinear dynamical systems defined on smooth connected Riemannian manifolds and characterizes properties of Lyapunov functions with respect to the Riemannian distance function. We extend classical Lyapunov converse theorems for dynamical systems in R n to dynamical systems evolving on Riemannian manifolds. This is performed by restricting our analysis to the so called normal neighborhoods of equilibriums on Riemannian manifolds. By employing the derived properties of Lyapunov functions, we obtain the stability of perturbed dynamical systems on Riemannian manifolds.

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Some properties of the Riemannian distance function and the position vector X, with applications to the construction of Lyapunov functions

Cited by 9 publications

References 4 publications

Geometry-aware manipulability learning, tracking, and transfer

Geometry-aware manipulability learning, tracking, and transfer

Geometry-aware Manipulability Learning, Tracking and Transfer

A Local Characterization of Lyapunov Functions and Robust Stability of Perturbed Systems on Riemannian Manifolds

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