Abstract
Edge detection is one of the main steps in the image processing field, especially in bio-medical imaging, to diagnose a disease or trace its progress. The transfer of medical images makes them more susceptible to quality degradation due to any imposed noise. Hence, the protection of this data against noise is a persistent need. The efficiency of fractional-order filters to detect fine details and their high noise robustness, unlike the integer-order filters, it renders them an attractive solution for biomedical edge detection. In this work, two novel central fractional-order masks are proposed with their detailed mathematical proofs. The fractional-order parameter gives an extra degree of freedom in designing different masks. The noise performance of the proposed masks is evaluated upon applying Salt and Pepper noise and Gaussian noise. Numerical results proved that the proposed masks outperform the integer-order masks regarding both types of noise, achieving higher Peak Signal to Noise Ratio. As a practical application, the proposed fractional-order edge detection masks are employed to enhance the Diabetic Retinopathy disease diagnosis. © 2021 by the authors. Licensee MDPI, Basel, Switzerland.
Authors
Ismail S.M., Said L.A., Madian A.H., Radwan A.G.
Keywords
Diabetic retinopathy; Edge detection; Fractional-order; Noise
Document Type
Journal
Source
Computers, Vol. 10, Art. No. 30, PP. 1 to 28, Doi: 10.3390/computers10030030