Presentation
Real-Time Dynamic IR-drop Prediction for IR ECO
DescriptionDuring the IR Engineering Change Order (ECO) stage, cell moving leads to uncertain IR-drop results, requiring designers to explore multiple ECO candidates in each iteration to find a solution that effectively mitigates IR-drop, resulting in long evaluation time. Although machine learning (ML)-based predictors have been proposed to expedite IR-drop evaluation, partial simulations are still needed to update features after ECO, taking over an hour and delaying IR-drop results. In this work, we propose a real-time dynamic IR-drop estimation method based on an XGBoost model with a global view of a cell's surroundings. After ECO, our method provides dynamic IR-drop results in minutes without running any simulations and thus achieve real-time estimation. This allows designers to evaluate multiple ECO candidates concurrently in a single iteration. We conducted the experiments on five ECO candidates of an industrial design with 3𝑛𝑚 technology. The results show that the proposed model can effectively predict the IR-drop variations of moved cells after ECO with over 93% of fixed cells detected and an average MAE of 8.75𝑚𝑉 achieved. Furthermore, our method achieves an 88𝑋 speedup over Voltus (commercial tool) and a 64𝑋 speedup over traditional ML predictors when evaluating a single ECO candidate. The speedup is expected to increase as the number of ECO candidates increases.
Event Type
Research Manuscript
TimeMonday, June 234:30pm - 4:45pm PDT
Location3006, Level 3
EDA
EDA4: Power Analysis and Optimization