DETECTION OF DENSE, OVERLAPPING, GEOMETRIC OBJECTS.

Adele Peskin, Boris Wilthan, Michael Majurski
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引用次数: 3

Abstract

Using a unique data collection, we are able to study the detection of dense geometric objects in image data where object density, clarity, and size vary. The data is a large set of black and white images of scatterplots, taken from journals reporting thermophysical property data of metal systems, whose plot points are represented primarily by circles, triangles, and squares. We built a highly accurate single class U-Net convolutional neural network model to identify 97 % of image objects in a defined set of test images, locating the centers of the objects to within a few pixels of the correct locations. We found an optimal way in which to mark our training data masks to achieve this level of accuracy. The optimal markings for object classification, however, required more information in the masks to identify particular types of geometries. We show a range of different patterns used to mark the training data masks, and how they help or hurt our dual goals of location and classification. Altering the annotations in the segmentation masks can increase both the accuracy of object classification and localization on the plots, more than other factors such as adding loss terms to the network calculations. However, localization of the plot points and classification of the geometric objects require different optimal training data.

密集,重叠,几何物体的检测。
使用独特的数据集,我们能够研究在物体密度,清晰度和大小变化的图像数据中密集几何物体的检测。数据是一组大的黑白散点图,取自报道金属系统热物性数据的期刊,其图点主要由圆形、三角形和正方形表示。我们建立了一个高度精确的单类U-Net卷积神经网络模型,在一组定义的测试图像中识别97%的图像物体,并将物体的中心定位到正确位置的几个像素以内。我们找到了一种最佳的方法来标记我们的训练数据掩码,以达到这种精度水平。然而,用于物体分类的最佳标记需要更多的掩模信息来识别特定类型的几何形状。我们展示了一系列用于标记训练数据掩码的不同模式,以及它们如何帮助或损害我们的位置和分类的双重目标。改变分割掩码中的注释,比在网络计算中添加损失项等其他因素更能提高目标分类和定位的准确性。然而,图点的定位和几何目标的分类需要不同的最优训练数据。
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