Stability of Haptic Rendering: Discretization, Quantization, Time Delay, and Coulomb Effects

Author

Diolaiti, Nicola ; Niemeyer, Günter ; Barbag, Federico ; Salisbury, J. Kenneth, Jr.

Author_Institution

Dept. of Electron., Comput. Sci. & Syst., Bologna Univ.

Volume

22

Issue

2

fYear

2006

fDate

4/1/2006 12:00:00 AM

Firstpage

256

Lastpage

268

Abstract

Rendering stiff virtual objects remains a core challenge in the field of haptics. A study of this problem is presented, which relates the maximum achievable object stiffness to the elements of the control loop. In particular, we examine how the sampling rate, quantization, computational delay, and amplifier dynamics interact with the inertia, natural viscous, and Coulomb damping of the haptic device. Nonlinear effects create distinct stability regions, and many common devices operate stably, yet in violation of passivity criteria. An energy-based approach provides theoretical insights, supported by simulations, experimental data, and a describing function analysis. The presented results subsume previously known stability conditions

Keywords

delays; friction; haptic interfaces; Coulomb effects; amplifier dynamics; discretization; energy-based approach; haptic rendering; maximum achievable object stiffness; natural viscous damping; quantization; sampling rate; stiff virtual objects; time delay; Bandwidth; Computational modeling; Computer interfaces; Delay effects; Friction; Haptic interfaces; Quantization; Rendering (computer graphics); Sampling methods; Stability; Amplifier dynamics; Coulomb friction; haptic interfaces; passivity; quantization; virtual objects;

fLanguage

English

Journal_Title

Robotics, IEEE Transactions on

Publisher

ieee

ISSN

1552-3098

Type

jour

DOI

10.1109/TRO.2005.862487

Filename

1618739