Optimized Brain Tumor Detection: A Dual-Module Approach for MRI Image Enhancement and Tumor Classification

Project Code :TCMAPY1391

Objective

The project aims to develop a deep learning framework for automatic brain tumor detection and segmentation from MRI images using MobileNet and DenseNet architectures. Objectives include classifying MRI images into tumor and non-tumor categories, optimizing computational resources for real-time applications, and enhancing detection accuracy through improved feature propagation. The framework will also extend to localize tumor regions within images. Performance will be validated using benchmark datasets, focusing on metrics like accuracy, precision, recall, and segmentation quality. Ultimately, the project seeks to support clinical decision-making and integrate into real-time diagnostic systems, improving early diagnosis and patient outcomes.

Abstract

Brain tumor detection and segmentation from MRI images are critical tasks for early diagnosis and effective treatment planning in medical imaging. This project aims to develop an advanced deep learning-based framework for automatic tumor classification and segmentation, leveraging state-of-the-art neural network architectures, namely MobileNet and DenseNet, to improve detection accuracy and computational efficiency. MobileNet's lightweight design facilitates real-time applications by reducing model complexity without sacrificing performance, while DenseNet's densely connected layers enhance feature propagation, leading to more robust and precise classification outcomes.

The system is designed to classify brain MRI images into two categories: tumor and non-tumor. The classification networks employ MobileNet and DenseNet to maximize accuracy and optimize computational resources. MobileNet provides a streamlined approach suitable for edge computing and mobile devices, ensuring faster inference times, while DenseNet's improved gradient flow contributes to higher detection accuracy.

For segmentation tasks, the framework can be extended to localize tumor regions within the brain, potentially using complementary segmentation techniques. The integration of these models aims to enhance diagnostic capabilities by providing automated, reliable, and accurate tumor detection to support clinical decision-making. This approach holds promise for improving early diagnosis, reducing the need for invasive diagnostic procedures, and potentially integrating into real-time diagnostic systems in healthcare settings.

The project will evaluate the proposed methods using benchmark datasets, with performance metrics including accuracy, precision, recall, and segmentation quality to validate its effectiveness in real-world medical imaging scenarios.

KEYWORDS: - Brain Tumor, MRI, MobileNet, DenseNet, Deep Learning, Accuracy and Robust.

NOTE: Without the concern of our team, please don't submit to the college. This Abstract varies based on student requirements.