Fingerprint processing based on phase portrait model
In recent decades, automatic fingerprint identification system has attracted significant interest among the scientific research community. Though large amount of effort has been made in both the academic and industrial communities, there are still unsolved problems. Noisy image processing and l...
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| Format: | Theses and Dissertations |
| Published: |
2008
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| Online Access: | https://hdl.handle.net/10356/4645 |
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| Institution: | Nanyang Technological University |
| Summary: | In recent decades, automatic fingerprint identification system has
attracted significant interest among the scientific research
community. Though large amount of effort has been made in both the
academic and industrial communities, there are still unsolved
problems. Noisy image processing and large scale database processing
are two typical problems.
Fingerprint images consist of oriented texture. Therefore the
orientation information plays a very important role in fingerprint
processing. Moreover, the orientation of the fingerprint follows a
certain structure that is not random. Such oriented structure
provides a possibility to recover the orientation information in
fingerprints corrupted by noise, even for a large noise patch which
cannot be solved by the traditional gradient based methods. Accurate
reconstruction of the orientations is useful for fingerprint
filtering, segmentation, classification and recognition.
Several methods have been proposed to reconstruct the fingerprint
orientation. In this thesis, phase portrait model approach is used.
The first order phase portrait is demonstrated to be robust for both
occluded and noisy fingerprints. It also has the capability to
describe the orientation patterns of the core point and delta point
in a fingerprint image. Therefore a method based on the first order
phase portrait is proposed to reconstruct the local orientation near
the core and delta points. Furthermore, considering the regularity
of the fingerprint orientation and linearity of the first order
phase portrait, a model based on the piecewise phase portrait is
used to predict the orientations far away from the singular point
region. The advantage of this prediction model is that it provides a
way to overcome the large patch of noise or missing orientation. To
obtain the fingerprint orientation with higher precision, more
complicated model based on the constrained nonlinear phase portrait
approach is proposed. The model employs the advantages of both the
first order and high order phase portrait model. Hence accurate
reconstructed orientations at both the local and global area can be
obtained simultaneously.
This thesis also addresses fingerprint classification using the
coefficients of the constrained nonlinear phase portrait model
together with the singularities information. Since the coefficients
of the constrained nonlinear phase portrait model play a key role in
reconstructing the fingerprint orientation, it is also expected to
be able to effectively classify fingerprints. A fingerprint
classification algorithm using the orientation model and the
singular points' information which complement the orientation
information is developed and is shown to have good classification
performance. |
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