Abstract
Brain tumors have become a leading cause of death around the globe. The main reason for this epidemic is the difficulty conducting a timely diagnosis of the tumor. Fortunately, magnetic resonance images (MRI) are utilized to diagnose tumors in most cases. The performance of a Convolutional Neural Network (CNN) depends on many factors (i.e., weight initialization, optimization, batches and epochs, learning rate, activation function, loss function, and network topology), data quality, and specific combinations of these model attributes. When we deal with a segmentation or classification problem, utilizing a single optimizer is considered weak testing or validity unless the decision of the selection of an optimizer is backed up by a strong argument. Therefore, optimizer selection processes are considered important to validate the usage of a single optimizer in order to attain these decision problems. In this paper, we provides a comprehensive comparative analysis of popular optimizers of CNN to benchmark the segmentation for improvement. In detail, we perform a comparative analysis of 10 different state-of-the-art gradient descent-based optimizers, namely Adaptive Gradient (Adagrad), Adaptive Delta (AdaDelta), Stochastic Gradient Descent (SGD), Adaptive Momentum (Adam), Cyclic Learning Rate (CLR), Adaptive Max Pooling (Adamax), Root Mean Square Propagation (RMS Prop), Nesterov Adaptive Momentum (Nadam), and Nesterov accelerated gradient (NAG) for CNN. The experiments were performed on the BraTS2015 data set. The Adam optimizer had the best accuracy of 99.2% in enhancing the CNN ability in classification and segmentation.
Highlights
A disease is defined as a disorder of function in a living being
Four classes of the CIFAR-10 data set are chosen for the experiments.The proposed EIOM is compared with other optimizers, namely AdaGrad, AdaDelta, RMSProp, Adaptive Momentum (Adam), and Cyclic Learning Rate (CLR) that produced 97% accuracy [31]
Convolutional Neural Network (CNN) architecture to measure the performance for brain tumor segmentation
Summary
A disease is defined as a disorder of function in a living being. If we drill down the definition, it can be defined as a disorder of structure or function in the division of cells in a living organism. Though there are many medical imaging modalities available to differentiate the characteristics of brain tumors, magnetic resonance images (MRIs) are the most commonly used medical imaging modalities due to its advantage of visual analysis and its flexibility in the domain of computer-aided analysis of medical images. They [3] focused their experimental analysis on the fully annotated brain tumor segmentation (BraTS) challenge 2013 data set using the well-defined training and testing splits, thereby allowing us to compare directly and quantitatively a wide variety of other methods. Deep learning (DL) and Convolutional Neural Networks (CNN) stood at the center of all these developments in brain MRI image analysis and computer interventions and proved their adoption to be a successful execution to drive for continuous improvements.
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