基于熵和边界引导蒙特卡罗采样和定向区域搜索的语义分割改进

Zitang Sun, S. Kamata, Ruojing Wang
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引用次数: 0

摘要

语义分割既需要较大的接受野,又需要准确的空间信息。虽然现有的基于全卷积网络的方法已经大大提高了预测精度,但在分析小目标和边界区域时,预测结果仍然不令人满意。我们提出了一种改进算法来改进前网络生成的结果。该方法采用改进的双分支网络生成分割掩码和语义边界,作为细化算法的输入。我们创造性地引入信息熵来表示每个像素对应的神经网络预测的置信度。将信息熵与语义边界相结合,通过蒙特卡罗采样,可以捕获那些难以预测的低置信度像素。每个选定的像素都将作为定向局部搜索和细化的初始种子。根据初始种子,我们的目的相当于搜索相邻的高置信度区域,重新标记方法是基于高置信度结果。值得注意的是,我们的方法采用了基于梯度下降的定向区域搜索策略,可以有效地找到高置信度区域。我们的方法可以灵活地嵌入到现有的编码器骨干中,计算成本很低。我们的改进算法可以进一步提高当前方法在城市景观和PASCAL VOC数据集上的准确性。在评估一些小对象时,我们的方法超越了大多数最先进的方法。
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Semantic Segmentation Refinement Using Entropy and Boundary-guided Monte Carlo Sampling and Directed Regional Search
Semantic segmentation requires both a large receptive field and accurate spatial information. Although existing methods based on a fully convolutional network have greatly improved the accuracy, the prediction results still do not show satisfactory when parsing small objects and boundary regions. We propose a refinement algorithm to improve the result generated by the front network. Our method takes a modified double-branches network to generate both segmentation masks and semantic boundaries, which serve as refinement algorithms' input. We creatively introduce information entropy to represent the confidence of the neural network's prediction corresponding to each pixel. The information entropy combined with the semantic boundary can capture those unpredictable pixels with low-confidence through Monte Carlo sampling. Each selected pixel will serve as the initial seed for directed local search and refinement. According to the initial seed, our purpose is tantamount to searching the neighbor high-confidence regions, and the re-labeling approach is based on high-confidence results. Remarkably, our method adopts a directed regional search strategy based on gradient descent to find the high-confidence region effectively. Our method can be flexibly embedded into the existing encoder backbone at a trivial computational cost. Our refinement algorithm can further improve the state of the art method's accuracy both on Cityscapes and PASCAL VOC datasets. In evaluating some small objects, our method surpasses most of the state of the art methods.
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