Self-Attention to Operator Learning-based 3D-IC Thermal Simulation
By: Zhen Huang , Hong Wang , Wenkai Yang and more
Potential Business Impact:
**Speeds up computer chip cooling design 842 times.**
Thermal management in 3D ICs is increasingly challenging due to higher power densities. Traditional PDE-solving-based methods, while accurate, are too slow for iterative design. Machine learning approaches like FNO provide faster alternatives but suffer from high-frequency information loss and high-fidelity data dependency. We introduce Self-Attention U-Net Fourier Neural Operator (SAU-FNO), a novel framework combining self-attention and U-Net with FNO to capture long-range dependencies and model local high-frequency features effectively. Transfer learning is employed to fine-tune low-fidelity data, minimizing the need for extensive high-fidelity datasets and speeding up training. Experiments demonstrate that SAU-FNO achieves state-of-the-art thermal prediction accuracy and provides an 842x speedup over traditional FEM methods, making it an efficient tool for advanced 3D IC thermal simulations.
Similar Papers
DeepOHeat-v1: Efficient Operator Learning for Fast and Trustworthy Thermal Simulation and Optimization in 3D-IC Design
Machine Learning (CS)
Makes computer chips cool faster and better.
A Novel Frequency-Spatial Domain Aware Network for Fast Thermal Prediction in 2.5D ICs
Machine Learning (CS)
Predicts computer chip heat faster and better.
LOGLO-FNO: Efficient Learning of Local and Global Features in Fourier Neural Operators
Machine Learning (CS)
Helps computers understand fast, swirling movements.