Separability filter method is a reliable method for pupil detection. However, so far this method is implemented for detecting pupil of normal eye, while for abnormal eye such as cataract and glaucoma patients; they have different characteristics of pupil such as color, shape and radius size of pupil. In this paper we propose to use separability filter for detecting pupil of abnormal patients with different characteristics. We faced a problem about radius size, shape and color of pupil; therefore we implemented Hough Transform, Blob area and Brightness for identifying input images before applying separability filter. The experiment results show that we can increase performance of pupil detection for abnormal eye to be 95.65%.

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R Supriyanti, Hitoshi Habe, Masatsugu Kidode, Satoru Nagata. Cataract Screening by Specular Reflection and Texture Analysis, Communications of SIWN, 2009. 6: 59-64.

R Supriyanti, Hitoshi Habe, Masatsugu Kidode and Satoru Nagata. Extracting Appearance Information inside the Pupil for Cataract Screening. IAPR Conference on Machine Vision Application. Tokyo, Japan. 2009: 342-345.

R Supriyanti, Y Ramadhani, Hitoshi Habe, Masatsugu Kidode. Performance of Various Digital Cameras for Cataract Screening Techniques based on Digital Images. International Seminar of Electrical Power, Electronics, Communications, Control and Informatics (EECCIS), Malang, East Java, Indonesia, December, 2010.

R Supriyanti, Y Ramadhani. The Achievement of Various Shapes of Specular Reflections for Cataract Screening System Based on Digital Images. International Conference on Biomedical Engineering and Technology (ICBET). Kualalumpur, Malaysia. 2011:

R Supriyanti, B Setiawan, HB Widodo, E Murdyantoro. Detecting Pupil and Iris under Uncontrolled Illumination using Fixed-Hough Circle Transform. International Journal of Signal Processing, Image Processing and Pattern Recognition (IJSIP). 2012; 5(4): 175-188.

F Arnia, N Pramita. Enhancement of Iris Recognition System Based on Phase Phase Only Correlation. TELKOMNIKA Telecommunication Computing Electronics and Control. 2011: 9(2): 387-394.

IKG Darma Putra, A Cahyawan, Y Perdana. Low-Cost Based Eye Tracking and Eye Gaze Estimation. TELKOMNIKA Telecommunication Computing Electronics and Control. 2011; 9(2): 377-386.

Michal Ciesla, Przemyslaw. Eye Pupil Location Using Webcam. Jagiellonian University. Poland. 2012.

Samira Kooshkestani, Mohammad Pooyan, Hamed Sadjedi. A New Method for Iris Recognition Systems Based on Fast Pupil Localization. Lecture Notes in Computer Science. 2008. 5072: 555-564.

Haider Ali, Ahmad Ali2, Riaz Ul Husnain, Roman Khan, Mohsin Khan, Ihsan Ullah Khan. Automatic Localization of Iris Using Region Properties. International Journal of Computer Science and Network Security. 2011: 11(7): 93-97.

Zhaofeng He, Tieniu Tan, Zhenan Sun. Iris Localization via Pulling and Pushing. The 18th International Conference on Pattern Recognition. Hongkong. 2006: 366-369.

Peng Yang, Bo Du, Shiguang Shan, Wen Gao. A Novel Pupil Localization Method Based on Gaboreye Model and Radial Symmetry Operator. International Conference on Image Processing (IClP). Singapore. 2004: 67-70.

TA Camus, R Wildes. Reliable and Fast Eye Finding in Close-up Images. The 16th International Conference on Pattern Recognition (ICPR). Canada. 2002: 389-394.

Libor Masek. Recognition of Human Iris Patterns for Biometric Identification. PhD thesis, The University of Western Australia, 2003.

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K Fukui, Y Osamu. Facial Feature Point Extraction Method Based on Combination of Shape Extraction and Pattern Matching. Systems and Computers in Japan. 1998; 29(6): 49-58.