Go to DBLP homepagePhysics-Informed Matrix Factorization Operator
Abstract: Matrix factorization is a fundamental characterization model in machine learning and is usually solved using mathematical decomposition reconstruction loss. However, matrix factorization is a data-driven model whose results depend on data quality, making it susceptible to noise. Inspired by physics, the law of conservation of energy is used to introduce physical laws into matrix factorization, which is called Physics-informed Matrix Factorization operator (PiMF). The PiMF operator uses the heat conduction equation to construct the energy objective function for matrix factorization, thereby retaining the mathematical model’s decomposition meaning and satisfying the interpretability of physics. The PiMF follows the physical laws, thereby suppressing irregular or sudden noise signals that violate these physical principles. The solutions of the PiMF operator include more comprehensive knowledge of mathematics and physics, which improves the ability to generalize complex data, especially for noisy data. We demonstrate the consistency of the energy objective function and the mathematical model, which verifies the feasibility of matrix factorization using physical energy laws. In addition, the physical interpretability of the PiMF operator is proved from the perspective of energy decline. This study proposes two practical algorithms for PiMF in classification and clustering tasks, enhancing the practicability of matrix factorization by incorporating task-specific prior information constraints. The experimental results of PiMF for classification and clustering demonstrate the advantages of the proposed operator. The importance of physics-informed matrix factorization is verified, especially for noisy data.
External IDs:dblp:journals/pami/WuTJLLLMY26
Loading