Abstract
Background of the studyBreast cancer is the most fatal disease that widely affects women. When the cancerous lumps grow from the cells of the breast, it causes breast cancer. Self-analysis and regular medical check-ups help for detecting the disease earlier and enhance the survival rate. Hence, an automated breast cancer detection system in mammograms can assist clinicians in the patient's treatment. In medical techniques, the categorization of breast cancer becomes challenging for investigators and researchers. The advancement in deep learning approaches has established more attention to their advantages to medical imaging issues, especially for breast cancer detection. AimThe research work plans to develop a novel hybrid model for breast cancer diagnosis with the support of optimized deep-learning architecture. MethodsThe required images are gathered from the benchmark datasets. These collected datasets are used in three pre-processing approaches like “Median Filtering, Histogram Equalization, and morphological operation”, which helps to remove unwanted regions from the images. Then, the pre-processed images are applied to the Optimized U-net-based tumor segmentation phase for obtaining accurate segmented results along with the optimization of certain parameters in U-Net by employing “Adapted-Black Widow Optimization (A-BWO)”. Further, the detection is performed in two different ways that is given as model 1 and model 2. In model 1, the segmented tumors are used to extract the significant patterns with the help of the “Gray-Level Co-occurrence Matrix (GLCM) and Local Gradient pattern (LGP)”. Further, these extracted patterns are utilized in the “Dual Model accessed Optimized Long Short-Term Memory (DM-OLSTM)” for performing breast cancer detection and the detected score 1 is obtained. In model 2, the same segmented tumors are given into the different variants of CNN, such as “VGG19, Resnet150, and Inception”. The extracted deep features from three CNN-based approaches are fused to form a single set of deep features. These fused deep features are inserted into the developed DM-OLSTM for getting the detected score 2 for breast cancer diagnosis. In the final phase of the hybrid model, the score 1 and score 2 obtained from model 1 and model 2 are averaged to get the final detection output. ResultsThe accuracy and F1-score of the offered DM-OLSTM model are achieved at 96 % and 95 %. ConclusionExperimental analysis proves that the recommended methodology achieves better performance by analyzing with the benchmark dataset. Hence, the designed model is helpful for detecting breast cancer in real-time applications.
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