基于物理约束字典学习的熔丝加工过程温度场监测

Yanglong Lu, Yan Wang
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引用次数: 1

摘要

压缩感知利用数据在互反空间中表示的稀疏性来实现数据压缩。然而,压缩感知的性能取决于测量和基矩阵。为了最大限度地提高恢复系数向量的稀疏度,字典学习已经发展到优化特定信号的基矩阵。然而,从理论上讲,字典学习的最佳结果很难在制造过程监控中实现,因为物理实现受到传感器数量、传感器物理尺寸和制造环境中传感器可及性的限制。在这项工作中,提出了一种物理约束字典学习(PCDL)方法,在考虑这些限制的情况下分别优化测量矩阵和基矩阵。PCDL的独特之处在于,在优化的测量矩阵中,每一行只有一个非零条目,因此直接确定传感器放置的物理位置。传感器可及性的附加约束也被纳入。用热成像技术证明了所提出的PCDL用于熔丝制造过程监控。利用优化的基矩阵和优化位置的有限像素值重建高分辨率热图像,以实现高效监测。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Temperature Field Monitoring in Fused Filament Fabrication Process Based on Physics-Constrained Dictionary Learning
Compressed sensing takes advantage of the sparsity of data representation in the reciprocal space and achieves data compression. The performance of compressed sensing however depends on the measurement and basis matrices. To maximize the sparsity level of recovered coefficient vectors, dictionary learning has been developed to optimize the basis matrices for specific signals. Nevertheless, the theoretically optimal results from dictionary learning can be difficult to achieve in manufacturing process monitoring because the physical realization is restricted by the number of sensors, physical sizes of sensors, and sensor accessibility in the manufacturing environment. In this work, a physics-constrained dictionary learning (PCDL) approach is proposed to optimize the measurement and basis matrices separately with the considerations of these restrictions. The uniqueness of the PCDL is that there is only one non-zero entry in each row in the optimized measurement matrix so that the physical locations for the sensor placement are directly determined. Additional constraints of sensor accessibility are also incorporated. The proposed PCDL is demonstrated with thermal imaging for fused filament fabrication process monitoring. High-resolution thermal images are reconstructed with the optimized basis matrix and the limited pixel values at the optimized locations to allow for efficient monitoring.
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