dc.description.abstract |
This dissertation presents a novel and efficient multiple objects tracking technique
dealing long-term and complete occlusion. The technique is based on a new low cost
object appearance model to associate objects. This work is primarily focused on the
improvement of resource utilization aspects, targeting real-time embedded
applications with limited resources. Moreover, a comparative accuracy analysis is also
performed to ensure that the proposed work is in close agreement with state of the art
methods in terms of accuracy. This dissertation is mainly composed of three
contributions.
The first contribution presents a K-means based model for object appearance
modeling. The appearance model combined with the simple object spatial position is
used to infer the objects association/tracking decision. The objects appearance model
and temporal spatial position is updated for one to one object/blob association
throughout the sequence of video. However, for one-to-many blob/objects
associations after the onset of occlusion a statistical distance measure is introduced for
object association to deal occlusion. The comparative evaluation of resource
utilization on standard datasets shows the superior performance of our approach in
terms of computational time and/or memory as compared to the state-of-the-art
baseline methods. In our second contribution, a low cost K-means based object
appearance model is presented to achieve a faster solution for multiple objects
tracking. In our first contribution and the recent literature, the object appearance is
updated in every frame. However, there is no need to update the appearance model in
every frame as more often it tends not to change. For this purpose, a novel histogram
based appearance update model is applied on every detected blob to decide when to
update the appearance model. Moreover, the employed histogram based cluster
initialization further reduces the overall computational cost as the standard K-means
algorithm can take more time to converge due to improper initialization of cluster
centroids. The presented low cost model achieves much faster solution as compared to
the baseline K-means and GMM based models with comparable memory
requirements and accuracy.
xi
The first two contributions are about realizing a low cost multiple objects
tracking method using merge and split approach for occlusion reasoning. The
accuracy of the merge and split is compromised during occlusion. However, the
emphasis of third contribution is on the improvement of accuracy during occlusion
with reasonable resource utilization. In this contribution the K-means based method is
extended to straight through approach, which tracks the individual objects despite
occlusion thus increasing the accuracy. Low cost shape and appearance models are
combined for pixel association during occlusion. Furthermore, two-pass outlier
rejection technique is employed to address the issue of outliers. Our approach
provides superior accuracy as compared to the state-of-the-art online multiple objects
tracking approaches with comparable resource utilization.
The prime objective of all the contributions of this dissertation is to provide a
resource efficient solution of multiple objects tracking with comparable accuracy to
the state of the art. In literature, the main focus of researchers is towards the aim of
the accuracy with compromise on the resource utilization aspects of the system. The
trending embedded smart cameras have started to replace the conventional PC based
surveillance systems due to their low cost and built-in intelligence. To achieve real
time solution with limited available resource, smart cameras require efficient
algorithms with minimum resource utilization. With efficient resource utilization, the
multiple objects tracking algorithms proposed in this dissertation, provides very
strong grounds for the development of smart camera based real time surveillance
solution. |
en_US |