3D relative pose estimation from six distances

Nikolas Trawny; Xun S. Zhou; Stergios Roumeliotis

3D relative pose estimation from six distances

Nikolas Trawny, Xun S. Zhou, Stergios Roumeliotis

Computer Science and Engineering

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

7 Scopus citations

Abstract

In this paper, we present three fast, hybrid numericalgebraic methods to solve polynomial systems in floating point representation, based on the eigendecomposition of a so-called multiplication matrix. In particular, these methods run using standard double precision, use only linear algebra packages, and are easy to implement. We provide the proof that these methods do indeed produce valid multiplication matrices, and show their relationship. As a specific application, we use our algorithms to compute the 3D relative translation and orientation between two robots, based on known egomotion and six robotto- robot distance measurements. Equivalently, the same system of equations arises when solving the forward kinematics of the general Stewart-Gough mechanism. Our methods can find all 40 solutions, trading off speed (0.08s to 1.5s, depending on the choice of method) for accuracy.

Original language	English (US)
Title of host publication	Robotics
Subtitle of host publication	Science and Systems V
Editors	Jose A. Castellanos, Yoky Matsuoka, Jeff Trinkle
Publisher	MIT Press Journals
Pages	233-240
Number of pages	8
ISBN (Print)	9780262514637
State	Published - Jan 1 2010
Event	International Conference on Robotics Science and Systems, RSS 2009 - Seattle, United States Duration: Jun 28 2009 → Jul 1 2009

Publication series

Name	Robotics: Science and Systems
Volume	5
ISSN (Print)	2330-7668
ISSN (Electronic)	2330-765X

Other

Other	International Conference on Robotics Science and Systems, RSS 2009
Country/Territory	United States
City	Seattle
Period	6/28/09 → 7/1/09

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title = "3D relative pose estimation from six distances",

abstract = "In this paper, we present three fast, hybrid numericalgebraic methods to solve polynomial systems in floating point representation, based on the eigendecomposition of a so-called multiplication matrix. In particular, these methods run using standard double precision, use only linear algebra packages, and are easy to implement. We provide the proof that these methods do indeed produce valid multiplication matrices, and show their relationship. As a specific application, we use our algorithms to compute the 3D relative translation and orientation between two robots, based on known egomotion and six robotto- robot distance measurements. Equivalently, the same system of equations arises when solving the forward kinematics of the general Stewart-Gough mechanism. Our methods can find all 40 solutions, trading off speed (0.08s to 1.5s, depending on the choice of method) for accuracy.",

author = "Nikolas Trawny and Zhou, {Xun S.} and Stergios Roumeliotis",

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pages = "233--240",

editor = "Castellanos, {Jose A.} and Yoky Matsuoka and Jeff Trinkle",

booktitle = "Robotics",

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AU - Trawny, Nikolas

AU - Zhou, Xun S.

AU - Roumeliotis, Stergios

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N2 - In this paper, we present three fast, hybrid numericalgebraic methods to solve polynomial systems in floating point representation, based on the eigendecomposition of a so-called multiplication matrix. In particular, these methods run using standard double precision, use only linear algebra packages, and are easy to implement. We provide the proof that these methods do indeed produce valid multiplication matrices, and show their relationship. As a specific application, we use our algorithms to compute the 3D relative translation and orientation between two robots, based on known egomotion and six robotto- robot distance measurements. Equivalently, the same system of equations arises when solving the forward kinematics of the general Stewart-Gough mechanism. Our methods can find all 40 solutions, trading off speed (0.08s to 1.5s, depending on the choice of method) for accuracy.

AB - In this paper, we present three fast, hybrid numericalgebraic methods to solve polynomial systems in floating point representation, based on the eigendecomposition of a so-called multiplication matrix. In particular, these methods run using standard double precision, use only linear algebra packages, and are easy to implement. We provide the proof that these methods do indeed produce valid multiplication matrices, and show their relationship. As a specific application, we use our algorithms to compute the 3D relative translation and orientation between two robots, based on known egomotion and six robotto- robot distance measurements. Equivalently, the same system of equations arises when solving the forward kinematics of the general Stewart-Gough mechanism. Our methods can find all 40 solutions, trading off speed (0.08s to 1.5s, depending on the choice of method) for accuracy.

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M3 - Conference contribution

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A2 - Castellanos, Jose A.

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PB - MIT Press Journals

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ER -

3D relative pose estimation from six distances

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