基于卷积神经网络和反卷积的脑肿瘤检测

B. S. Sai, N. K., T. V. Reddy, T. Suma, P. Ashok babu
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引用次数: 4

摘要

肿瘤是指细胞在人体某一特定部位的异常生长。脑肿瘤也是其中之一,它能够引起严重的精神残疾和与中枢神经系统有关的问题,这些组织的过度生长最终可能导致进一步的并发症,如肌肉麻痹,也可能导致致命的死亡。考虑到所有这些冲突,在早期阶段检测肿瘤是至关重要的,否则它最终会对神经系统造成致命的影响。MRI(磁共振成像)扫描可以帮助我们诊断这些脑肿瘤,但是检测这些肿瘤的过程是人为驱动的和艰巨的,而且神经科医生通常会花费合理的时间来检测这些肿瘤,这种检测方法也会导致人为错误,因此为了避免这些冲突,非常需要选择有效的路径和设计有效的脑肿瘤检测模型。本研究工作提出了一种基于卷积神经网络的自主肿瘤检测技术模型,用于检测恶性肿瘤Gliomas,在检测肿瘤的过程中使用了VGG16和VGG-19等鲁棒网络,并在VGG-16模型上使用反卷积处理进行更好的特征提取,最后一层使用CRF-RNN进行分类,而不是使用FCN。这些用于脑肿瘤检测的不同模型都表现良好,在vgg16和VGG19网络上分别训练得到了95%和96%的非常高的准确率。然后,该模型对VGG-16进行反卷积处理,再进行CRF-RNN,也能有效地对脑肿瘤进行分类,准确率达到92.3%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Brain Tumour Detection Using Convolutional Neural Networks and Deconvolution
A Tumor is known as the aberrant growth of cells over a particular region of human body. Brain tumor also being one among those and it is capable of causing serious mental disabilities and issues related to the central nervous system, excessive growth of these tissues could ultimately lead to further complications like muscle paralysis, may also lead to fatal death. Considering all these conflicts detection of the tumor in very early stages is essential or else it would end up in causing lethal effects to the nervous system. MRI (Magnetic resonance imaging) scans helps us in diagnosing these brain tumors, but the process involved in detecting these tumors is Human-driven and arduous, also neurologists do generally take reasonable time to detect these tumors, this method of detection can also lead to human errors, so to avoid all these conflicts it is highly required to choose cogentpaths and design an effective model for the detection of brain tumors. This research work has proposed a model that involves an autonomous tumor detection technique for detecting cancerous tumor named Gliomas using convolutional neural networks, robust networks like VGG16 and VGG-19 are used in the process of detection of tumor and further this research has used deconvolution process on the VGG-16 model for a better feature extraction followed by CRF-RNN in the final layer for classification purpose instead of FCN. All these different models used for detecting brain tumor have performed well and has yielded us a very high accuracy rate of 95% and 96% when trained on VGG-16 and VGG19 network respectively. Then, the model has applied deconvolutional process on VGG-16 followed by CRF-RNN is also be able to classify the brain tumor effectively and it have yielded us a good accuracy rate of 92.3%.
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