Full-chip CMP modelling based on Fully Convolutional Network leveraging White Light Interferometry
For IC design teams, this work accelerates layout manufacturability verification by providing a more efficient CMP model, though it is incremental as it applies existing CNN techniques to a specific domain.
The authors propose a deep learning model combining White Light Interferometry and Atomic Force Microscopy to predict full-chip post-CMP nanotopography with nanometer-scale accuracy, addressing the time-consuming calibration and hardware demands of existing Density Step Height models.
As time-to-market is crucial in the Integrated Circuit (IC) industry, speeding up layout manufacturability verifi-cation is essential. Chemical-Mechanical Polishing (CMP) plays a vital role in IC fabrication but is significantly influenced by Layout-Dependent Effects (LDE). An accurate and efficient CMP model enables design teams to correct surface unevenness before fabrication, reducing costs and accelerating the design phase. However, existing models often rely on Density Step Height (DSH) modeling, which is time-consuming for calibration and requires substantial hardware resources for fine-grained predictions. In this paper, we propose combining the advantages of two surface analysis techniques, White Light Interfer-ometry (WLI) and Atomic Force Microscopy (AFM), to train a deep learning model. This model aims to predict full-chip post-CMP nanotopography with nanometer-scale accuracy. Our deep learning model is based on a Convolutional Neural Network (CNN) and follows a two-step pipeline. The model is trained on each technique separately, resulting in a detailed full-chip CMP model.