Kamel K. Mohammed

Work place: Center for virus research and Studies, Al-Azhar University, Cairo, 11754, Egypt

E-mail: tawfickamel@gmail.com

Website:

Research Interests:

Biography

Dr. Kamel K. Mohammed is an accomplished BioMed engineering researcher specializing in ultrasound imaging, AI, and medical innovation. Kamel holds a PhD in Biomedical Engineering and Systems from Cairo University, he developed an objective evaluation method for ultrasound images, enhancing image quality and disease detection. Published in renowned journals, his work includes AI applications for COVID-19. He excels in medical imaging and is an active participant in innovation programs, securing 2nd place in Siemens Healthineers’ Think Tank Certification Program. His interdisciplinary work contributes to novel healthcare solutions, exploring metaverse technology. Well-regarded in his field, he continuously pushes the boundaries of biomedical research, aiming to improve healthcare outcomes with AI integration. Kamel's research interests include developing AI systems for automated analysis of medical images and bio signals. His current work focuses on applying deep learning for lung cancer detection in CT scans. He also has experience in designing wearable sensors for mobile health applications. He has co-authored over 18 publications and serves as member in scientific research school of Egypt (SRSEG).

Author Articles
Infrared Images Spectra Multi-class Classification Model Based on Deep Learning

By Asmaa S. Abdo Kamel K. Mohammed Rania Ahmed Heba Alshater Samar A. Aly Ashraf Darwish Aboul Ella Hassanein

DOI: https://doi.org/10.5815/ijisa.2024.04.02, Pub. Date: 8 Aug. 2024

The classification of Fourier Transform Infrared spectra images is crucial in chemometrics. This paper proposes an efficient model based on deep learning approaches for enhancement and classification of the Fourier Transform Infrared Spectra (FTIR) images. The proposed model integrates three deep learning models including ResNet101, EfficientNetB0, and Wavelet Scattering transform (WST) to extract several features from FTIR.  Then the obtained features were fused in conjunction with standard statistical feature extraction. It followed by a subsequent classification phase that employs a Convolutional Neural Network (CNN) architecture, which demonstrates high accuracy in classifying the infrared spectra images into six different classes of ligands and their metal complexes. During the training phase, the network’s weights are iteratively updated using the Adam optimization algorithm. This model addresses the challenge of small and imbalanced datasets through an image oversampling process. Using random over-sampling technique, it enhances the training process and overall classification performance. The extracted features were analyzed using t-distributed Stochastic Neighbor Embedding (t-SNE) to visualize high-dimensional data in two dimensions. The results of the proposed model show high classification accuracy of 0.91%, low error rate of 0.08%, a sensitivity of 0.89% and a precision of 0.89%, false positive rate of 0.01%, F1 score of 0.89, Matthews Correlation Coefficient of 0.87 and Kappa of 0.68.

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