Quantum mechanism-based convolution model for the classification of pathogenic bacteria
- Isra Naz,
- Jamal Hussain Shah,
- ,
- Muhammad Rafiq,
- Gyu Sang Choi
- COMSATS University Islamabad,
- ,
- Keimyung University,
- Yeungnam University
Research Output: Contribution to journal Article Peer-review
Open access
Sustainable Development Goals
- SDG 6 Clean Water and Sanitation
Abstract
Water, especially drinking water, should be clean and free of disease-causing bacteria because of its critical role in life. However, it isn’t easy to identify and classify them rapidly at an early stage. Primarily, the examination of water is performed manually to check the contamination level. Some researchers have proposed techniques to detect and classify bacteria images, but this field still needs more attention. In this research work, a robust Quantum Convolutional Neural Network (QCNN) classification model is proposed to classify the six major categories of pathogenic bacteria. For the acquisition of pathogen images, different slides are created through the gram-staining process, and then images are captured from those slides. DIBaS is the publicly available dataset that provides these slides captured through gram-staining, which is used to evaluate the proposed methodology. So, in the first step, database preprocessing, small patches are extracted from slide images. However, the extracted patches were not clear and very useful, so the Enhanced Super-Resolution Generative Adversarial Network Model (ESRGAN) was applied to images to improve the image quality of extracted patches. The third step is to extract the deep features and classify bacterial images using the QCNN model, in which the Quantum Convolutional layer is added, and classical data is converted into quantum data to perform classification. Based on the results of classification experiments using the QCNN model, the accuracy is 96.54%.
Publication Information
Output type
Research Output: Contribution to journal Article Peer-review
Original language
EnglishPages from-to (Number of pages)
Pages 137747 - 137757 (11 pages)Journal (Volume, Issue Number)
IEEE Access (Volume 11)Publication milestones
- Published - 01/12/2023
Publication status
Published - 01/12/2023
External Publication IDs
- ORCID: /0000-0001-7428-2272/work/147900698
- Scopus: 85180267657
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Final published version, 1.9 MB
License:CC BY-NC-ND, opens in new tab
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