More Like this

1. The physics of optical computing

   https://doi.org/10.1038/s42254-023-00645-5  

   McMahon, Peter L. (December 2023, Nature Reviews Physics)
2. Physics-Guided, Physics-Informed, and Physics-Encoded Neural Networks and Operators in Scientific Computing: Fluid and Solid Mechanics

   https://doi.org/10.1115/1.4064449  

   Faroughi, Salah A; Pawar, Nikhil M; Fernandes, Célio; Raissi, Maziar; Das, Subasish; Kalantari, Nima K; Kourosh_Mahjour, Seyed (April 2024, Journal of Computing and Information Science in Engineering)

   Abstract Advancements in computing power have recently made it possible to utilize machine learning and deep learning to push scientific computing forward in a range of disciplines, such as fluid mechanics, solid mechanics, materials science, etc. The incorporation of neural networks is particularly crucial in this hybridization process. Due to their intrinsic architecture, conventional neural networks cannot be successfully trained and scoped when data are sparse, which is the case in many scientific and engineering domains. Nonetheless, neural networks provide a solid foundation to respect physics-driven or knowledge-based constraints during training. Generally speaking, there are three distinct neural network frameworks to enforce the underlying physics: (i) physics-guided neural networks (PgNNs), (ii) physics-informed neural networks (PiNNs), and (iii) physics-encoded neural networks (PeNNs). These methods provide distinct advantages for accelerating the numerical modeling of complex multiscale multiphysics phenomena. In addition, the recent developments in neural operators (NOs) add another dimension to these new simulation paradigms, especially when the real-time prediction of complex multiphysics systems is required. All these models also come with their own unique drawbacks and limitations that call for further fundamental research. This study aims to present a review of the four neural network frameworks (i.e., PgNNs, PiNNs, PeNNs, and NOs) used in scientific computing research. The state-of-the-art architectures and their applications are reviewed, limitations are discussed, and future research opportunities are presented in terms of improving algorithms, considering causalities, expanding applications, and coupling scientific and deep learning solvers. 

   more » « less
3. Aggregation Methods for Computing Steady States in Statistical Physics

   https://doi.org/10.1137/22M1530628  

   Earle, Gabriel; Van Koten, Brian (September 2023, Multiscale Modeling & Simulation)

   We give a new proof of local convergence of a multigrid method called iterative aggregation/disaggregation (IAD) for computing steady states of Markov chains. Our proof leads naturally to precise and interpretable estimates of the asymptotic rate of convergence. We study IAD as a model of more complex methods from statistical physics for computing nonequilibrium steady states, such as the nonequilibrium umbrella sampling method of Warmflash, Bhimalapuram, and Dinner [J. Chem. Phys., 127 (2007), 154112]. We explain why it may be possible to use methods like IAD to efficiently calculate steady states of processes in statistical physics and how to choose parameters to optimize efficiency. 

   more » « less
4. Physics-inspired Ising Computing with Ring Oscillator Activated p-bits

   https://doi.org/10.1109/NANO54668.2022.9928681  

   Aadit, N. A; Grimaldi A.; Finocchio, G; Camsari, KY (October 2022, 2022 IEEE 22nd International Conference on Nanotechnology (NANO))
5. FPGA-Accelerated Machine Learning Inference as a Service for Particle Physics Computing

   https://doi.org/10.1007/s41781-019-0027-2  

   Duarte, Javier; Harris, Philip; Hauck, Scott; Holzman, Burt; Hsu, Shih-Chieh; Jindariani, Sergo; Khan, Suffian; Kreis, Benjamin; Lee, Brian; Liu, Mia; et al (December 2019, Computing and Software for Big Science)