采用混合策略的三维点云感知引导质量度量法

Yujie Zhang;Qi Yang;Yiling Xu;Shan Liu
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摘要

全参考点云质量评估(FR-PCQA)旨在利用可用参考点推断失真点云的质量。现有的全参考点云质量评估指标大多忽视了人类视觉系统(HVS)会根据不同的失真程度动态处理视觉信息(即高质量样本的失真检测和低质量样本的外观感知)这一事实,并使用统一的特征来衡量点云质量。为了弥补这一差距,我们在本文中提出了一种以感知为导向的混合度量(PHM),该度量可根据失真程度自适应地利用两种视觉策略来预测点云质量:为了测量高质量样本中的可见差异,PHM 考虑了遮蔽效应,并将纹理复杂度作为绝对差异的有效补偿因子;另一方面,PHM 利用光谱图理论来评估低质量样本中的外观退化。图形上几何信号的变化和频谱图小波系数的变化分别用来描述几何和纹理外观退化的特征。最后,用非线性方法将两个部分的结果结合起来,得出被测点云的总体质量分数。在五个独立数据库上进行的实验结果表明,PHM 达到了最先进的(SOTA)性能,并在多种失真环境下显著提高了性能。代码可在 https://github.com/zhangyujie-1998/PHM 网站上公开获取。
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Perception-Guided Quality Metric of 3D Point Clouds Using Hybrid Strategy
Full-reference point cloud quality assessment (FR-PCQA) aims to infer the quality of distorted point clouds with available references. Most of the existing FR-PCQA metrics ignore the fact that the human visual system (HVS) dynamically tackles visual information according to different distortion levels (i.e., distortion detection for high-quality samples and appearance perception for low-quality samples) and measure point cloud quality using unified features. To bridge the gap, in this paper, we propose a perception-guided hybrid metric (PHM) that adaptively leverages two visual strategies with respect to distortion degree to predict point cloud quality: to measure visible difference in high-quality samples, PHM takes into account the masking effect and employs texture complexity as an effective compensatory factor for absolute difference; on the other hand, PHM leverages spectral graph theory to evaluate appearance degradation in low-quality samples. Variations in geometric signals on graphs and changes in the spectral graph wavelet coefficients are utilized to characterize geometry and texture appearance degradation, respectively. Finally, the results obtained from the two components are combined in a non-linear method to produce an overall quality score of the tested point cloud. The results of the experiment on five independent databases show that PHM achieves state-of-the-art (SOTA) performance and offers significant performance improvement in multiple distortion environments. The code is publicly available at https://github.com/zhangyujie-1998/PHM .
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