dc.description.abstract |
Identification and verification of human beings is very important because of
today’s security condition throughout the world. From the beginning of 19th century, iris
is being used for recognition of humans. Recent efforts in computer vision have made it
possible to develop automated systems that can recognize individuals efficiently and with
high accuracy. The main functional components of existing iris-recognition systems
consist of image acquisition, iris localization, feature extraction and matching. While
designing the system, one must understand physical nature of the iris, image processing
and their analysis to make an accurate system. The most difficult and time consuming
part of iris recognition is iris localization. In this thesis, performance of iris localization
and normalization processes in iris recognition systems has been enhanced through
development of effective and efficient strategies. Bit plane and wavelet based features
has been analyzed for recognition.
Iris localization is the most important step in iris recognition systems. Iris is
localized by first finding the boundary between pupil and iris using different methods for
different databases. This is because the iris image acquiring devices and environment is
different. Non-circular boundary of pupil is obtained by dividing the circular pupil into
specific points and then these points are forced to shift at exact boundary position of
pupil which are linearly joined.
The boundary between iris and sclera is obtained by finding points of maximum
gradient in radially outwards different directions. Redundant points are discarded by
finding certain distance from the center of the pupil to the concerned relevant point. This
is because the distance between center of pupil and center of iris is very small. The
domain for different directions is left and right sectors of iris when pupil center is at the
origin of the axes.
Eyelids are detected by fitting parabolas using points satisfying specific criterions.
Experimental results show that the efficiency of the proposed method is very high as
compared to other existing methods.
Improved localization results are reported using proposed methods. The
experiments are carried out for four different iris image datasets. Correct localization rate
of 100% (pupil circular boundary), 99.8% (non-circular pupil), 99.77% (iris outer
-ii-boundary), 98.91% (upper eyelid detection) and 96.6% (lower eyelid detection) has been
achieved for different datasets.
To compensate the change in size of the iris due to pupil constriction / dilation
and camera to eye distance, different normalization schemes have been designed and
implemented based on difference reference points.
Mainly two different features extraction methodologies have been proposed. One
is related to the bit planes of normalized image and other utilizes the properties of
wavelet transform.
Recognition results based on bit plane features of the iris have also been obtained
and correct recognition rate of up to 99.64% has been achieved using CASIA version 3.0.
Results on other databases have also provided encouraging performance with accuracy of
94.11%, 97.55% and 99.6% on MMU, CASIA version 1.0 and BATH iris databases
respectively.
Different wavelets have been applied to get best iris recognition results. Different
levels of wavelet transforms (Haar, Daubechies, Symlet, Coiflet, Biorthogonal and
Mexican hat) along with different number of coefficients have been used. Coiflet wavelet
resulted in high accuracies of 99.83%, 96.59%, 98.44% and 100% on CASIA version 1.0,
CASIA version 3.0, MMU and BATH iris databases respectively. |
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