Implementation, design and methodology

Implementation, design and methodology

Research results in the School of Engineering

  • Auteur: Marín-Hurtado, Ana Julieth; Escobar-Mejía, Andrés; Hernández Gómez, Kevin Alejandro; Echeverry Correa, Julián David; Orozco Gutiérrez, Álvaro Ángel
  • Éditeur: Universidad Tecnológica de Pereira
  • Collection: Trabajos de investigación
  • eISBN Pdf: 9789587229080
  • Lieu de publication:  Pereira , Colombia
  • Année de publication: 2023
  • Pages: 72
An end-to-end methodology based on deep learning for the detection and localization of microcalcifications in digital mammograms introduces a novel methodology designed for the preprocessing and localization of clusters of microcalcifications (CM) in mammograms, with the primary goal of facilitating early detection of breast cancer. The preprocessing phase encompasses artifact removal and breast segmentation, achieved through advanced techniques such as contrast enhancement and adaptive thresholding. Addressing the challenge of pectoral muscle removal, a common obstacle in mammogram analysis, involves a multi-step strategy incorporating background estimation and K-means segmentation. To localize CM, a convolutional neural network (CNN) is leveraged for the classification of regions of interest (ROI) as either containing CM or not. Subsequently, potential CM-containing ROIs undergo contrast enhancement techniques to amplify CM visibility, followed by filtering to eliminate false positives based on geometric and intensity characteristics. The effectiveness of the methodology is validated using two extensively used datasets, namely mini-MIAS and DDSM, demonstrating superior performance compared to existing methods across various metrics including breast and pectoral muscle segmentation, as well as CM classification. Additionally, a prototype CAD system is developed, seamlessly integrating all processing stages and offering a user-friendly interface for mammogram analysis.
  • Cover
  • Copyright page
  • Title page
  • Contents
  • Introduction
  • 1. Adaptive Inertia for Grid-Forming Control Scheme Applied to MMC Terminal
    • 1. Introduction
    • 2. Problem Statement
    • 3. Modular Multilevel Converter
      • 3.1 Average Voltage Controller
      • 3.2. Individual Voltage Control
      • 3.3 The Reference Signal
    • 4. Virtual Synchronous Machine
      • 4.1. Active Power Loop
      • 4.2. Reactive Power Loop
    • 5. Adaptive Virtual Inertia
    • 6. Methodology
    • 7. Results and Discussions
    • 8. Conclusions
    • References
  • 2. An end-to-end methodology based on deep learning for the detection and localization of microcalcifications in digital mammograms
    • 1. Introduction
    • 2. Materials and Methods
      • 2.1. Datasets
      • 2.2. Artifact removal and breast segmentation
      • 2.3 Pectoral muscle removal
      • 2.4. MC localization
    • 3. Results and Discussion
      • 3.1. Artifacts deleted and breast segmentation test results
      • 3.2. Pectoral muscle removal test results
      • 3.3. CAD system interface design
    • 4. Conclusions
    • 5. Acknowledgements
    • References

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