Colour profile identification for networked surveillance tracking systems
In the advancement of digital technology today, current CCTV visual security surveillance systems with eventually be replaced by IP networked based visual security surveillance systems thereby paving the way for automated people surveillance tracking and recognition systems, which allow easy inte...
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| Format: | Final Year Project |
| Language: | English |
| Published: |
2010
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| Subjects: | |
| Online Access: | http://hdl.handle.net/10356/39419 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | In the advancement of digital technology today, current CCTV visual security
surveillance systems with eventually be replaced by IP networked based visual
security surveillance systems thereby paving the way for automated people
surveillance tracking and recognition systems, which allow easy integration into the
network. Current human recognition systems rely on face recognition algorithms such
as Viola-Jones face detection and Principal Component Analysis (PCA) but do not
consider the combination of coloured outfits that people wear. The proposed solution
is to design the Intelligent Tracking Unit (ITU) to be installed in the Intelligent
Network Location-Tracking system, which can be easily connected to any network in
order to automatically track and recognise people. This report introduces the colour
matching ability of the ITU to simulate tracking of a coloured test picture which
resembles people wearing various coloured outfits. The study conducted prior to the
development of this algorithm on the BGR and HSI components of the colour model
revealed that the Hue values are closely correlated to the colour of the test paper,
provided that the colours were not greyscale. Another finding revealed that the Hue
values had the least standard deviation as compared to the BGR and HSI colour
components. This made it favourable for the development of the Hue Clustering
algorithm, which takes a background masked image and transforms it into a Hue
Profile consisting of a series of Hue Cluster Centroids. It was also found that although
the BGR values had reached their upper or lower limits, the inaccuracy of hue values
were insignificant. Experiments conducted using the Hue Clustering algorithm yielded
expected results which conformed to the intention of the design. Optimal values for
the Hue Clustering algorithm were also determined to ensure the correct number of
colours detected. Finally, the Hue Profile Comparator algorithm was designed and
implemented to return a percentage match point for two Hue Profiles. The experiment
was conducted for the cameras which had their field of view directed at the same
image, and the results yielded expected values of 95.91% match point, confirming the
successful implementation of this algorithm. |
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