A differential equation approach to swept volumes

Author

Blackmore, D. ; Leu, M.C.

Author_Institution

New Jersey Inst. of Technol., Newark, NJ, USA

fYear

1990

fDate

21-23 May 1990

Firstpage

143

Lastpage

149

Abstract

An approach to the analysis of swept volumes is introduced. It is shown that every smooth Euclidean motion or sweep, can be identified with a first-order, linear, ordinary differential equation. This sweep differential equation provides useful insights into the topological and geometrical nature of the swept volume of an object. A certain class, autonomous sweeps, is identified by the form of the associated differential equation, and several properties of the swept volumes of the members of this class are analyzed. The results are applied to generate swept volumes for a number of objects. Implementation of the sweep differential equation approach with computer-based numerical and graphical methods is also discussed

Keywords

computational geometry; differential equations; linear algebra; autonomous sweeps; computational geometry; differential equation; graphical methods; linear algebra; numerical methods; smooth Euclidean motion; swept volumes; Algorithm design and analysis; Differential equations; Machining; Manufacturing automation; Motion analysis; Motion planning; Orbital robotics; Robotics and automation; Solid modeling; Topology;

fLanguage

English

Publisher

ieee

Conference_Titel

Computer Integrated Manufacturing, 1990., Proceedings of Rensselaer's Second International Conference on

Conference_Location

Troy, NY

Print_ISBN

0-8186-1966-X

Type

conf

DOI

10.1109/CIM.1990.128088

Filename

128088