Tracking through singularities and discontinuities by random sampling

Author

Deutscher, J. ; North, B. ; Bascle, B. ; Blake, A.

Author_Institution

Dept. of Eng. Sci., Oxford Univ., UK

Volume

2

fYear

1999

fDate

1999

Firstpage

1144

Abstract

Some issues in markerless tracking of human body motion are addressed. Extended Kalman filters have commonly been applied to kinematic variables, to combine predictions consistent with plausible motion, with the incoming stream of visual measurements. Kalman filtering is applicable only when the underlying distribution is approximately Gaussian. Often this assumption proves remarkably robust. There are two pervasive circumstances under which the Gaussianity assumption can break down. The first is kinematic singularity and the second is at joint endstops. Failure of Kalman filtering under these circumstances is illustrated. The non-Gaussian nature of the distributions is demonstrated experimentally by means of Monte Carlo simulation. Random simulation (particle filtering or Condensation) proves to provide a robust alternative algorithm for tracking that can also deal with these difficult conditions

Keywords

Kalman filters; Monte Carlo methods; motion estimation; random processes; sampling methods; Condensation; Gaussianity assumption; Kalman filtering; Monte Carlo simulation; extended Kalman filters; human body motion; incoming stream; joint endstops; kinematic singularity; kinematic variables; markerless tracking; particle filtering; plausible motion; random sampling; random simulation; robust alternative algorithm; underlying distribution; visual measurements; Biometrics; Cameras; Filtering; Humans; Kalman filters; Kinematics; Leg; Motion measurement; Sampling methods; Tracking;

fLanguage

English

Publisher

ieee

Conference_Titel

Computer Vision, 1999. The Proceedings of the Seventh IEEE International Conference on

Conference_Location

Kerkyra

Print_ISBN

0-7695-0164-8

Type

conf

DOI

10.1109/ICCV.1999.790409

Filename

790409