The principle of minimum specificity as a basis for evidential reasoning
Processing and Management of Uncertainty in Knowledge-Based Systems on Uncertainty in knowledge-based systems. International Conference on Information
Artificial Intelligence
What is Dempster-Shafer's model?
Advances in the Dempster-Shafer theory of evidence
Estimation with Applications to Tracking and Navigation
Estimation with Applications to Tracking and Navigation
Belief functions on real numbers
International Journal of Approximate Reasoning
Decision making in the TBM: the necessity of the pignistic transformation
International Journal of Approximate Reasoning
Practical uses of belief functions
UAI'99 Proceedings of the Fifteenth conference on Uncertainty in artificial intelligence
Editorial: Special issue in memory of Philippe Smets (1938--2005)
International Journal of Approximate Reasoning
International Journal of Approximate Reasoning
Multi-camera people tracking using evidential filters
International Journal of Approximate Reasoning
Theories of Trust for Communication Protocols
ATC '09 Proceedings of the 6th International Conference on Autonomic and Trusted Computing
IEEE Transactions on Multimedia - Special issue on integration of context and content
Hierarchical and conditional combination of belief functions induced by visual tracking
International Journal of Approximate Reasoning
IEEE Transactions on Systems, Man, and Cybernetics, Part B: Cybernetics
Continuous belief functions to qualify sensors performances
ECSQARU'11 Proceedings of the 11th European conference on Symbolic and quantitative approaches to reasoning with uncertainty
Particle filtering in the Dempster--Shafer theory
International Journal of Approximate Reasoning
| Hi-index | 0.00 |
The paper develops an approach to joint tracking and classification based on belief functions as understood in the transferable belief model (TBM). The TBM model is identical to the classical model except all probability functions are replaced by belief functions, which are more flexible for representing uncertainty. It is felt that the tracking phase is well handled by the classical Kalman filter but that the classification phase deserves amelioration. For the tracking phase, we derive a minimal set of assumptions needed in the TBM approach in order to recover the classical relations. For the classification phase, we distinguish between the observed target behaviors and the underlying target classes which are usually not in one-to-one correspondence. We feel the results obtained with the TBM approach are more reasonable than those obtained with the corresponding Bayesian classifiers.