Brain Tumor Classification Using Deep Learning Technique - A Comparison between Cropped, Uncropped, and Segmented Lesion Images with Different Sizes

Alqudah, Ali Mohammad; Alquraan, Hiam; Abu-Qasmieh, Isam; Alqudah, Amin; Al-Sharu, Wafaa N.

doi:10.30534/ijatcse/2019/155862019

Cited by 86 publications

(45 citation statements)

References 28 publications

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“…It is commonly used in multivariant classifications purposes. The fully connected layer has nodes with the same number of output classes [38]. In the paper, we utilized the properties in MATLAB ® 2019 [39] to build our own CNN which consists of 18 layers and employs it in discriminating the numerals.…”

Section: Convolutional Neural Network (Cnn)mentioning

confidence: 99%

Recognition of Handwritten Arabic and Hindi Numerals Using Convolutional Neural Networks

Alqudah

Alquran

et al. 2021

Applied Sciences

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Arabic and Hindi handwritten numeral detection and classification is one of the most popular fields in the automation research. It has many applications in different fields. Automatic detection and automatic classification of handwritten numerals have persistently received attention from researchers around the world due to the robotic revolution in the past decades. Therefore, many great efforts and contributions have been made to provide highly accurate detection and classification methodologies with high performance. In this paper, we propose a two-stage methodology for the detection and classification of Arabic and Hindi handwritten numerals. The classification was based on convolutional neural networks (CNNs). The first stage of the methodology is the detection of the input numeral to be either Arabic or Hindi. The second stage is to detect the input numeral according to the language it came from. The simulation results show very high performance; the recognition rate was close to 100%.

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Section: Convolutional Neural Network (Cnn)mentioning

confidence: 99%

Recognition of Handwritten Arabic and Hindi Numerals Using Convolutional Neural Networks

Alqudah

Alquran

et al. 2021

Applied Sciences

Self Cite

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“…Alqudah et al [ 36 ] put forth a new DCNN architecture with just 18 layers for classifying (grading) MR images into three classes of tumors including Meningioma, Glioma, and Pituitary. They used a public dataset containing 3064 brain MR images (T1 weighted contrast-enhanced).…”

Section: Dcnns Application In the Classification Of Brain Cancer Imentioning

confidence: 99%

The Application of Deep Convolutional Neural Networks to Brain Cancer Images: A Survey

Shirazi

Fornaciari

McDonnell

et al. 2020

JPM

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In recent years, improved deep learning techniques have been applied to biomedical image processing for the classification and segmentation of different tumors based on magnetic resonance imaging (MRI) and histopathological imaging (H&E) clinical information. Deep Convolutional Neural Networks (DCNNs) architectures include tens to hundreds of processing layers that can extract multiple levels of features in image-based data, which would be otherwise very difficult and time-consuming to be recognized and extracted by experts for classification of tumors into different tumor types, as well as segmentation of tumor images. This article summarizes the latest studies of deep learning techniques applied to three different kinds of brain cancer medical images (histology, magnetic resonance, and computed tomography) and highlights current challenges in the field for the broader applicability of DCNN in personalized brain cancer care by focusing on two main applications of DCNNs: classification and segmentation of brain cancer tumors images.

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“…Due to the easy accessibility and the ready availability, the Figshare MRI brain tumour dataset also has been used in many brain tumor classification and segmentation related research [15][16][17][18]. e dataset, which was initiated in 2015 and last updated in 2017 [13,16], carries an average classification accuracy in the range of 90-95% [14,16,19,20]. e authors in [16] achieved a classification average of 95% accuracy by using a modified CNN architecture while the authors in [15] achieved around 96% accuracy with an automatic content-based image retrieval (CBIR) system.…”

Section: Introductionmentioning

confidence: 99%

A Systematic Approach for MRI Brain Tumor Localization and Segmentation Using Deep Learning and Active Contouring

Gunasekara

Kaldera

Dissanayake

2021

Journal of Healthcare Engineering

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One of the main requirements of tumor extraction is the annotation and segmentation of tumor boundaries correctly. For this purpose, we present a threefold deep learning architecture. First, classifiers are implemented with a deep convolutional neural network (CNN) and second a region-based convolutional neural network (R-CNN) is performed on the classified images to localize the tumor regions of interest. As the third and final stage, the concentrated tumor boundary is contoured for the segmentation process by using the Chan–Vese segmentation algorithm. As the typical edge detection algorithms based on gradients of pixel intensity tend to fail in the medical image segmentation process, an active contour algorithm defined with the level set function is proposed. Specifically, the Chan–Vese algorithm was applied to detect the tumor boundaries for the segmentation process. To evaluate the performance of the overall system, Dice Score, Rand Index (RI), Variation of Information (VOI), Global Consistency Error (GCE), Boundary Displacement Error (BDE), Mean Absolute Error (MAE), and Peak Signal to Noise Ratio (PSNR) were calculated by comparing the segmented boundary area which is the final output of the proposed, against the demarcations of the subject specialists which is the gold standard. Overall performance of the proposed architecture for both glioma and meningioma segmentation is with an average Dice Score of 0.92 (also, with RI of 0.9936, VOI of 0.0301, GCE of 0.004, BDE of 2.099, PSNR of 77.076, and MAE of 52.946), pointing to the high reliability of the proposed architecture.

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Brain Tumor Classification Using Deep Learning Technique - A Comparison between Cropped, Uncropped, and Segmented Lesion Images with Different Sizes

Cited by 86 publications

References 28 publications

Recognition of Handwritten Arabic and Hindi Numerals Using Convolutional Neural Networks

Recognition of Handwritten Arabic and Hindi Numerals Using Convolutional Neural Networks

The Application of Deep Convolutional Neural Networks to Brain Cancer Images: A Survey

A Systematic Approach for MRI Brain Tumor Localization and Segmentation Using Deep Learning and Active Contouring

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