PolySeg Plus:使用具有成本效益的主动学习的深度学习的多边形分割

Abdelrahman I. Saad, Fahima A. Maghraby, Osama Badawy
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引用次数: 0

摘要

摘要提出了一种基于高效主动学习机制的深度卷积神经网络图像分割模型,命名为PolySeg Plus。它旨在解决缺乏标记数据和息肉发现假阳性率高的息肉分割问题。除了应用主动学习,帮助标记更多的图像样本外,还生成了一个由五个基准数据集组成的综合息肉数据集,以增加图像数量。为了增强捕获的图像特征,采用了局部共享特征方法,该方法利用相邻特征相互结合的能力来提高图像特征的质量,克服了条件随机特征方法的缺点。使用ResUNet++、ResUNet、UNet++和UNet模型进行医学图像分割。使用高斯滤波器去除图像中的高斯噪声,然后对图像进行增强,然后将其输入模型。除了通过超参数调优来优化模型性能外,还使用网格搜索来选择最优参数以使模型性能最大化。结果表明,在CVC-ClinicDB、CVC-ColonDB、ETIS Larib polyp DB、KVASIR-SEG和Kvasir-Sessile数据集上,与现有方法相比,该方法在息肉分割方面有显著的改进和适用性,Dice系数分别为0.9558、0.8947、0.7547、0.9476和0.6023。该方法不仅提高了单个数据集上的骰子系数,而且在综合数据集上也产生了更好的结果,这将有助于计算机辅助诊断系统的发展。
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PolySeg Plus: Polyp Segmentation Using Deep Learning with Cost Effective Active Learning
Abstract A deep convolution neural network image segmentation model based on a cost-effective active learning mechanism is proposed and named PolySeg Plus. It is intended to address polyp segmentation with a lack of labeled data and a high false-positive rate of polyp discovery. In addition to applying active learning, which assisted in labeling more image samples, a comprehensive polyp dataset formed of five benchmark datasets was generated to increase the number of images. To enhance the captured image features, the locally shared feature method is used, which utilizes the power of employing neighboring features together with one another to improve the quality of image features and overcome the drawbacks of the Conditional Random Features method. Medical image segmentation was performed using ResUNet++, ResUNet, UNet++, and UNet models. Gaussian noise was removed from the images using a gaussian filter, and the images were then augmented before being fed into the models. In addition to optimizing model performance through hyperparameter tuning, grid search is used to select the optimum parameters to maximize model performance. The results demonstrated a significant improvement and applicability of the proposed method in polyp segmentation when compared to state-of-the-art methods on the datasets CVC-ClinicDB, CVC-ColonDB, ETIS Larib Polyp DB, KVASIR-SEG, and Kvasir-Sessile, with Dice coefficients of 0.9558, 0.8947, 0.7547, 0.9476, and 0.6023, respectively. Not only did the suggested method improve the dice coefficients on the individual datasets, but it also produced better results on the comprehensive dataset, which will contribute to the development of computer-aided diagnosis systems.
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来源期刊
International Journal of Computational Intelligence Systems
International Journal of Computational Intelligence Systems 工程技术-计算机:跨学科应用
自引率
3.40%
发文量
94
期刊介绍: The International Journal of Computational Intelligence Systems publishes original research on all aspects of applied computational intelligence, especially targeting papers demonstrating the use of techniques and methods originating from computational intelligence theory. The core theories of computational intelligence are fuzzy logic, neural networks, evolutionary computation and probabilistic reasoning. The journal publishes only articles related to the use of computational intelligence and broadly covers the following topics: -Autonomous reasoning- Bio-informatics- Cloud computing- Condition monitoring- Data science- Data mining- Data visualization- Decision support systems- Fault diagnosis- Intelligent information retrieval- Human-machine interaction and interfaces- Image processing- Internet and networks- Noise analysis- Pattern recognition- Prediction systems- Power (nuclear) safety systems- Process and system control- Real-time systems- Risk analysis and safety-related issues- Robotics- Signal and image processing- IoT and smart environments- Systems integration- System control- System modelling and optimization- Telecommunications- Time series prediction- Warning systems- Virtual reality- Web intelligence- Deep learning
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