Integration of adaptive segmentation with heuristic-aided novel ensemble-based deep learning model for lung cancer detection using CT images

Pub Date : 2023-11-20 DOI:10.3233/idt-230071

Potti Nagaraja, Sumanth Kumar Chennupati

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Abstract

In recent days people are affected with lung cancer in, and the severe stage of this disease leads to death for human beings. Lung cancer is the second most typical cancer type to be found worldwide. Pulmonary nodules present in the lung can be used to identify cancer metastases because these nodules are visible in the lungs. Cancer diagnosis and region segmentation are the most important procedures because the prosperous prediction-affected area can accurately identify the variation in cancer and normal cell. By analyzing the lung nodules present in the image, the radiologists missed several useful low-density and small nodules, and this may tend to the diagnose process very difficult, and the radiologists needs more time to decide the prediction of affected lung nodules. Due to the radiologist’s physical inspection time and the possibility of missing nodules, automatic identification is needed to address these issues. In order to achieve this, a new hybrid deep learning model is developed for lung cancer detection with the help of CT images. At first, input images like CT images are gathered from the standard data sources. Once the images are collected, it undergoes for the pre-processing stage, where it is accomplished by Weighted mean histogram equalization and mean filtering. Consequently, a novel hybrid segmentation model is developed, in which Adaptive fuzzy clustering is incorporated with the Optimized region growing; here, the parameters are optimized by Improved Harris Hawks Optimization (IHHO). At last, the classification is accomplished by Ensemble-based Deep Learning Model (EDLM) that is constructed by VGG-16, Residual Network (ResNet) and Gated Recurrent Unit (GRU), in which the hyperparameters are tuned optimally by an improved HHO algorithm. The experimental outcomes and its performance analysis elucidate the effectiveness of the suggested detection model aids to early recognition of lung cancer.

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自适应分割与启发式集成深度学习模型的结合，用于肺癌CT图像检测

近年来，人们受到肺癌的影响，这种疾病的严重阶段导致人类死亡。肺癌是世界上第二常见的癌症类型。肺结节可用于鉴别癌症转移，因为这些结节在肺部可见。肿瘤诊断和区域分割是最重要的步骤，因为繁荣的预测影响区域可以准确地识别癌细胞和正常细胞的变化。放射科医生通过分析图像中出现的肺结节，遗漏了几个有用的低密度小结节，这可能会使诊断过程变得非常困难，放射科医生需要更多的时间来决定是否预测受影响的肺结节。由于放射科医生的物理检查时间和遗漏结节的可能性，需要自动识别来解决这些问题。为了实现这一目标，在CT图像的帮助下，开发了一种新的混合深度学习模型用于肺癌检测。首先，从标准数据源收集输入图像，如CT图像。采集到图像后，进行预处理，通过加权均值直方图均衡化和均值滤波来完成。为此，提出了一种新的混合分割模型，该模型将自适应模糊聚类与优化后的区域生长相结合;在这里，参数是由改进哈里斯鹰优化(IHHO)优化。最后，利用VGG-16、残余网络(ResNet)和门控循环单元(GRU)构建的基于集成的深度学习模型(EDLM)完成分类，其中超参数通过改进的HHO算法进行最优调整。实验结果及其性能分析说明了所提出的检测模型对肺癌早期识别的有效性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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