A Hybrid Feature-Based Machine Learning Framework for Automated Brain Tumor Classification

Authors

DOI:

https://doi.org/10.32350.umt-air.52.02

Keywords:

brain tumor classification, magnetic resonance imaging (MRI), hybrid feature-based model, handcrafted features, support vector machines (SVM), random forest, xgboost

Abstract

The classification of brain tumors using magnetic resonance imaging (MRI) is crucial for early diagnosis and efficient  decision-making  in  clinical  practice.  However,  manual  analysis  is  a  time-consuming  process  that may  introduce  observer  bias.  To  address  these  issues,  this  paper  presents  a  hybrid  feature-based  machine learning  model  for  automated  brain  tumor  classification,  integrating  both  handcrafted  and  deep  learning features  to  enhance  robustness  and  accuracy.  The  suggested  method  combines  Histogram  of  Oriented Gradients (HOG) to retrieve local texture data and high-level semantic details obtained with the help of the ResNet-50  deep  convolutional  neural  network.  The  hybrid  feature  vectors  are  then  classified  with  various machine  learning  classifiers,  such  as  Linear,  Gaussian,  and  Quadratic  Support  Vector  Machines  (SVMs), Logistic Regression, random forest, and XGBoost. The model has been tested using two publicly available benchmark datasets, viz., the Figshare Brain Tumor MRI dataset and Harvard Brain Tumor MRI dataset of a total of 10,286 MRI images. The experimental findings show that the hybrid framework is best in the Figshare dataset, where Quadratic SVM has the best classification accuracy of 97%, and the other models are 96% and 95% with Gaussian SVM and Logistic Regression, respectively. Random Forest yields optimal accuracy on the  more  difficult  Harvard  dataset  at  76%,  which  means  that  the  proposed  approach  can  be  generalized  to diverse data distributions. A further study is an ablation study, which supports the claim that the combination of  handcrafted and deep features is a significant performance metric on classification when compared to the features separately. The findings confirm that the hybrid framework has been developed as a suitable, robust, and universalized framework to classify automated multi-class brain tumors with the help of MRI images.

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Author Biographies

Anam Naveed, University of Engineering and Technology Taxila

The classification of brain tumors using Magnetic Resonance Imaging (MRI) is crucial for early diagnosis and efficient decision-making in clinical practice. However, manual analysis is a time-consuming process that may introduce observer bias. To address these issues, the current study presented a hybrid feature-based Machine Learning (ML) model for automated brain tumor classification, integrating both handcrafted and Deep Learning (DL) features to enhance robustness and accuracy.

Mamoona Sadia , University of Engineering and Technology Taxila

The classification of brain tumors using Magnetic Resonance Imaging (MRI) is crucial for early diagnosis and efficient decision-making in clinical practice. However, manual analysis is a time-consuming process that may introduce observer bias. To address these issues, the current study presented a hybrid feature-based Machine Learning (ML) model for automated brain tumor classification, integrating both handcrafted and Deep Learning (DL) features to enhance robustness and accuracy.

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Published

2025-12-07

How to Cite

Naveed, A., & Sadia , M. (2025). A Hybrid Feature-Based Machine Learning Framework for Automated Brain Tumor Classification. UMT Artificial Intelligence Review, 5(2), 23–40. https://doi.org/10.32350.umt-air.52.02

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