3D Force Prediction Using Fingernail Imaging with Automated Calibration

Authors

Thomas Grieve, University of Utah
Lucas Lincoln, University of Utah
Yu Sun, University of South FloridaFollow
John Hollerbach, University of Utah
Stephen Mascaro, University of Utah

Document Type

Conference Proceeding

Publication Date

3-2010

Keywords

imaging, haptic interfaces, flotor, 3D force prediction, fingernail imaging, automated calibration, normal forces, shear forces, magnetic levitation haptic device

Digital Object Identifier (DOI)

https://doi.org/10.1109/HAPTIC.2010.5444669

Abstract

This paper demonstrates a system for 3D force prediction using fingernail imaging, in which video images of the human fingernail are used to predict the normal and shear forces that occur when the finger is in contact with a flat surface. The automated calibration uses a magnetic levitation haptic device (MLHD) whose flotor has been modified to apply forces to the human fingerpad. The system accurately predicts forces with an RMS error of 0.3N normal force, 6% of the full range of 10N, and a shear force error of 0.3N, 3% of the full range of ±2.5N. This paper also demonstrates that varying the number of pixels used to represent the finger between 100 and 500 pixels has little effect on the results, indicating that a real-time application could use low-resolution images without loss of accuracy.

Was this content written or created while at USF?

Yes

Citation / Publisher Attribution

2010 IEEE Haptics Symposium, Waltham, MA, 2010, p. 113-120.

Scholar Commons Citation

Grieve, Thomas; Lincoln, Lucas; Sun, Yu; Hollerbach, John; and Mascaro, Stephen, "3D Force Prediction Using Fingernail Imaging with Automated Calibration" (2010). Computer Science and Engineering Faculty Publications. 103.
https://digitalcommons.usf.edu/esb_facpub/103