Physics-Informed Extreme Learning Machine (PIELM): Opportunities and Challenges
This is an incremental review paper that identifies opportunities and challenges for developing more robust PIELM frameworks in scientific and engineering applications.
The paper discusses the Physics-Informed Extreme Learning Machine (PIELM) approach for solving differential equations with challenging characteristics like sharp gradients and nonlinearities, noting its higher computational efficiency and accuracy compared to other physics-informed machine learning methods.
We are delighted to see the recent development of physics-informed extreme learning machine (PIELM) for its higher computational efficiency and accuracy compared to other physics-informed machine learning (PIML) paradigms. Since a comprehensive summary or review of PIELM is currently unavailable, we would like to take this opportunity to share our perspectives and experiences on this promising research direction. We can see that many efforts have been made to solve ordinary/partial differential equations (ODEs/PDEs) characterized by sharp gradients, nonlinearities, high-frequency behavior, hard constraints, uncertainty, multiphysics coupling, and interpretability. Despite these encouraging successes, many pressing challenges remain to be tackled, which also provides opportunities to develop more robust, interpretable, and generalizable PIELM frameworks for scientific and engineering applications.