Feature selection using adaptive manta ray foraging optimization for brain tumor classification

IF 3.7 4区 计算机科学 Q2 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE
K. S. Neetha, Dayanand Lal Narayan
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引用次数: 0

Abstract

Brain tumor is an anomalous growth of glial and neural cells and is considered as one of the primary causes of death worldwide. Therefore, it is essential to identify the tumor as soon as possible for reducing the mortality rate throughout the world. However, the classification of brain tumor is a challenging task due to presence of irrelevant features that cause misclassification during detection. In this research, the adaptive manta ray foraging optimization (AMRFO) is proposed for performing an effective feature selection to avoid the problem of overfitting while performing the classification. The adaptive control parameter strategy is incorporated in the AMRFO for enhancing the search process while selecting the feature subset. The linear intensity distribution information and regularization parameter-based intuitionistic fuzzy C-means algorithm namely LRIFCM is used to perform the segmentation of tumor regions. Next, LeeNET, gray-level co-occurrence matrix, local ternary pattern, histogram of gradients, and shape features are used to extract essential features from the segmented regions. Further, the attention-based long short-term memory (ALSTM) is used to classify the brain tumor types according to the features selected by AMRFO. The datasets utilized in this research study for the evaluation of AMRFO-ALSTM method are BRATS 2017, BRATS 2018, and Figshare brain datasets. Segmentation and classification are the two different evaluations examined for the AMRFO-ALSTM. The structural similarity index measure, Jaccard, dice, accuracy, and sensitivity are utilized during segmentation evaluation, while accuracy, specificity, sensitivity, precision, and F1-score are used during classification evaluation. The existing researches namely, transformer-enhanced convolutional neural network, Chan Vese (CV)-support vector machine, CV-K-nearest neighbor, deep convolutional neural network (DCNN), and salp water optimization with deep belief network are used to compare with the AMRFO-ALSTM. The accuracy of AMRFO-ALSTM for Figshare brain dataset is 99.80 which is a greater achievement when compared to the DCNN.

Abstract Image

利用自适应蝠鲼觅食优化技术为脑肿瘤分类选择特征
脑肿瘤是神经胶质细胞和神经细胞的异常生长,被认为是全球死亡的主要原因之一。因此,尽快识别肿瘤以降低全球死亡率至关重要。然而,脑肿瘤的分类是一项具有挑战性的任务,因为在检测过程中存在一些不相关的特征,导致分类错误。在这项研究中,提出了自适应鳐鱼觅食优化(AMRFO)来进行有效的特征选择,以避免在进行分类时出现过拟合问题。在 AMRFO 中加入了自适应控制参数策略,以便在选择特征子集时增强搜索过程。基于线性强度分布信息和正则化参数的直觉模糊 C-means 算法(即 LRIFCM)被用来对肿瘤区域进行分割。接下来,LeeNET、灰度共现矩阵、局部三元模式、梯度直方图和形状特征被用来提取分割区域的基本特征。然后,根据 AMRFO 选择的特征,使用注意力长短期记忆(ALSTM)对脑肿瘤类型进行分类。本研究用于评估 AMRFO-ALSTM 方法的数据集是 BRATS 2017、BRATS 2018 和 Figshare 脑数据集。分割和分类是对 AMRFO-ALSTM 的两种不同评估。在分割评估中使用了结构相似性指数度量、Jaccard、骰子、准确度和灵敏度,而在分类评估中使用了准确度、特异性、灵敏度、精确度和 F1 分数。与 AMRFO-ALSTM 相比,现有的研究包括变压器增强型卷积神经网络、支持向量机(CV)、CV-K-近邻、深度卷积神经网络(DCNN)和带深度信念网络的盐水优化。在 Figshare 大脑数据集上,AMRFO-ALSTM 的准确率为 99.80,与 DCNN 相比取得了更高的成绩。
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来源期刊
Pattern Analysis and Applications
Pattern Analysis and Applications 工程技术-计算机:人工智能
CiteScore
7.40
自引率
2.60%
发文量
76
审稿时长
13.5 months
期刊介绍: The journal publishes high quality articles in areas of fundamental research in intelligent pattern analysis and applications in computer science and engineering. It aims to provide a forum for original research which describes novel pattern analysis techniques and industrial applications of the current technology. In addition, the journal will also publish articles on pattern analysis applications in medical imaging. The journal solicits articles that detail new technology and methods for pattern recognition and analysis in applied domains including, but not limited to, computer vision and image processing, speech analysis, robotics, multimedia, document analysis, character recognition, knowledge engineering for pattern recognition, fractal analysis, and intelligent control. The journal publishes articles on the use of advanced pattern recognition and analysis methods including statistical techniques, neural networks, genetic algorithms, fuzzy pattern recognition, machine learning, and hardware implementations which are either relevant to the development of pattern analysis as a research area or detail novel pattern analysis applications. Papers proposing new classifier systems or their development, pattern analysis systems for real-time applications, fuzzy and temporal pattern recognition and uncertainty management in applied pattern recognition are particularly solicited.
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