Abstract
In this paper, we have proposed a novel methodology based on statistical features and different machine learning algorithms. The proposed model can be divided into three main stages, namely, preprocessing, feature extraction, and classification. In the preprocessing stage, the median filter has been used in order to remove salt-and-pepper noise because MRI images are normally affected by this type of noise, the grayscale images are also converted to RGB images in this stage. In the preprocessing stage, the histogram equalization has also been used to enhance the quality of each RGB channel. In the feature extraction stage, the three channels, namely, red, green, and blue, are extracted from the RGB images and statistical measures, namely, mean, variance, skewness, kurtosis, entropy, energy, contrast, homogeneity, and correlation, are calculated for each channel; hence, a total of 27 features, 9 for each channel, are extracted from an RGB image. After the feature extraction stage, different machine learning algorithms, such as artificial neural network, k-nearest neighbors' algorithm, decision tree, and Naïve Bayes classifiers, have been applied in the classification stage on the features extracted in the feature extraction stage. We recorded the results with all these algorithms and found that the decision tree results are better as compared to the other classification algorithms which are applied on these features. Hence, we have considered decision tree for further processing. We have also compared the results of the proposed method with some well-known algorithms in terms of simplicity and accuracy; it was noted that the proposed method outshines the existing methods.
Highlights
The human brain is one of the unsolved mysteries of science
The histogram equalization has been applied on each channel of RGB images in order to enhance the quality of these channels (ii) A novel method has been proposed to extract statistical features, namely, mean, variance, skewness, kurtosis, entropy, energy, contrast, homogeneity, and correlation from red, green, and blue channels of RGB images and concatenated to feed to the machine learning algorithms to classify the brain MRI images into normal and abnormal (iii) In the proposed method, we have applied different classification algorithms, such as k-nearest neighbor, decision tree, random forest, and Naïve Bayes to select an algorithm with the highest accuracy on the extracted features
The choice is to apply a simple machine learning algorithm, such as an artificial neural network with one or two hidden layers, k-nearest neighbor algorithm, decision tree, etc., but the problem with these algorithms is that we cannot feed complete image to these algorithms because it requires a lot of computation time
Summary
Its complexity has perplexed and vexed scientists till today. It contains over 85 ± 8 billion neurons with an equal number of nonneuronal cells. Brian controls and coordinates our body movements, homeostasis–body temperature, heart rate, blood pressure, and fluid balance. It is responsible for our emotions, fight or flight mood, memory, cognition, motor learning, and learning, remembering, and communicating processes [1]. There are 16,249 deaths per year, and the survival rate after diagnosis of a primary malignant brain and other CNS was 36%, lowest in 40+ age groups (90.2%), while in age group 0-14 years, survival rates were 97.3% [3]
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