Generation of Quadratic Force Fields from Potential Flow Fields for Distributed Manipulation

Distributed manipulation systems induce motions on objects through the application of many external forces. Many of these systems are abstracted as planar programmable force fields. Quadratic potential fields, which belong to such a class of fields, lend themselves to analytical study and exhibit useful stability properties. This paper introduces a new methodology to build Quadratic fields with simple devices using the naturally existing phenomena of airflow which is an improvement to the traditional use of the complicated programmable actuator arrays. It also provides a basis for the exploitation, in distributed manipulation, of natural phenomena like airflow, which require rigorous analysis and display stability difficulties. A demonstration and verification of the theoretical results for the special case of the elliptic field with air flows is also presented.