Function based sim-to-real learning for shape control of deformable free-form surfaces

For the shape control of deformable free-form surfaces, simulation plays a crucial role in establishing the mapping between the actuation parameters and the deformed shapes. The differentiation of this forward kinematic mapping is usually employed to solve the inverse kinematic problem for determini...

Full description

Saved in:
Bibliographic Details
Published inarXiv.org
Main Authors Tian, Yingjun, Fang, Guoxin, Su, Renbo, Wang, Weiming, Gill, Simeon, Weightman, Andrew, Wang, Charlie C L
Format Paper
LanguageEnglish
Published Ithaca Cornell University Library, arXiv.org 14.05.2024
Subjects
Actuation
Deformation
Formability
Free form
Kinematics
Learning
Mannequins
Mapping
Neural networks
Parameters
Physical simulation
Pipeline design
Shape control
Simulators
Surface geometry
Teaching methods
Online AccessGet full text

Cover

More Information
Summary:For the shape control of deformable free-form surfaces, simulation plays a crucial role in establishing the mapping between the actuation parameters and the deformed shapes. The differentiation of this forward kinematic mapping is usually employed to solve the inverse kinematic problem for determining the actuation parameters that can realize a target shape. However, the free-form surfaces obtained from simulators are always different from the physically deformed shapes due to the errors introduced by hardware and the simplification adopted in physical simulation. To fill the gap, we propose a novel deformation function based sim-to-real learning method that can map the geometric shape of a simulated model into its corresponding shape of the physical model. Unlike the existing sim-to-real learning methods that rely on completely acquired dense markers, our method accommodates sparsely distributed markers and can resiliently use all captured frames -- even for those in the presence of missing markers. To demonstrate its effectiveness, our sim-to-real method has been integrated into a neural network-based computational pipeline designed to tackle the inverse kinematic problem on a pneumatically actuated deformable mannequin.
ISSN:2331-8422